Discovery of candidate biomarkers of in vivo apoptosis by global profiling of caspase cleavage sites

ABSTRACT

The present invention relates to the discovery of novel biomarkers of in vivo apoptosis based on a large number of caspase-like cleavage sites. These biomarkers are useful for detection and quantification of apoptosis in a biological sample. The invention also provides synthetic peptides and proteins corresponding to neo-epitopes created by proteolytic processing of these cleavage sites. The synthetic peptides can be used as standards to enable identification and quantitation of these biomarkers using mass spectrometry. The synthetic proteins can be used to generate antibodies and other binding reagents specific for these biomarkers. Methods for detecting apoptosis as well as for diagnosing or for providing a prognosis for a disease or disease state characterized by apoptosis are also provided herein. Finally, the invention provides compositions and kits for performing the methods of the invention.

CROSS-REFERENCES TO RELATED APPLICATIONS

This application is a continuation of International Application No. PCT/US2009/052297, filed Jul. 30, 2009, which claims priority benefit of U.S. Provisional Application Ser. No. 61/084,845 filed on Jul. 30, 2008, the disclosure of which is incorporated by reference in its entirety for all purposes.

STATEMENT AS TO RIGHTS TO INVENTIONS MADE UNDER FEDERALLY SPONSORED RESEARCH AND DEVELOPMENT

This invention was made with Government support under NIH Grant Nos. F32 GM074458, R01 GM081051, NCRR 01614, R01 GM54762, P01 GM71790, and U54 GM074945. The Government has certain rights in this invention.

BACKGROUND OF THE INVENTION

The 600 or so proteases encoded in the human genome are involved in a diversity of biological processes. Some function as nonspecific degradative enzymes associated with protein catabolism, indiscriminately and exhaustively cleaving many protein substrates at many sites. In contrast, several others function as selective post-translational modifiers, cleaving a limited set of protein substrates, usually at only one or a few sites. Apoptosis is an important example of a biological process regulated by widespread but specific intracellular proteolysis, predominantly carried out by the caspase family of proteases. This genetically programmed and non-inflammatory form of cell death is a central component of homeostasis, tissue turnover, and development. Since apoptotic turnover of cells lies in direct opposition to the uncontrolled growth of tumor cells, a strong link also exists between apoptosis and cancer. Indeed, the terminal cellular effect of most chemotherapeutic compounds is induction of apoptosis (Kaufmann et al., Exp Cell Res, 2000, 256, 42-9).

The widespread intracellular proteolysis that is a hallmark of apoptosis is predominantly mediated by a family of aspartate-specific proteases termed caspases (Taylor et al., Nat Rev Mol Cell Biol, 2008, 9, 231-41). Apoptosis can be induced by extracellular death ligands, such as Fas ligand, TNF-α, or TRAIL, via the extrinsic pathway to activate caspase-8. It can also be induced by agents such as cytotoxic compounds, radiation, and other environmental stresses via the intrinsic pathway with release of proapoptotic factors from mitochondria to activate caspase-9. Initiator caspases-8 and -9 in turn activate downstream executioner caspases, among them caspases-3 and -7. Caspases then catalyze the inactivation of a multitude of prosurvival/antiapoptotic proteins and activation of antisurvival/proapoptotic proteins. The combined proteolytic events culminate in apoptotic cell death and clearance by phagocytes.

As a specific illustration, after receiving a cell death signal, apoptotic cells execute a cellular program that results in widespread and dramatic cellular changes that can include: (1) cell shrinkage and rounding due to the breakdown of the proteinaceous cytoskeleton; (2) the appearance of a dense cytoplasm and tight packing of cell organelles; (3) chromatin condensation into compact patches against the nuclear envelope; (4) discontinuity of the nuclear envelope and DNA fragmentation; (5) breakdown of the nucleus into several discrete chromatin bodies or nucleosomal units due to the degradation of DNA; (6) blebbing of the cell membrane into irregular buds. Near the conclusion of the apoptotic program, the cell breaks apart into several vesicles called apoptotic bodies, which are then typically phagocytosed.

Because the study of apoptotic pathways has ramifications for development of therapies for treatment of cancer, there is significant interest in gaining a better understanding of caspase proteolysis during apoptosis. For example, identification of new targets of proteolysis in apoptosis can lead to discovery of prosurvival/antiapoptotic factors, which can in turn serve as novel targets for cancer chemotherapy. A number of caspase substrates are active or established drug targets for treating cancer, including topoisomerases I and II, androgen receptor, thymidylate synthase, Bcl-2, IAPs, Mdm2 or Hdm2, PARP, HSP90, HDACs, the proteasome, Akt, MEK, Abl, EGFR, HER2, and VEGF, to name a few.

Products of caspase proteolysis may also serve as useful biomarkers of in vivo apoptosis. For example, serum levels of the caspase cleavage product of cytokeratin-18 have been used as a marker of chemotherapeutic efficacy in prostate, breast, and testicular cancers (Kramer et al., Br J Cancer, 2006, 94, 1592-8; Olofsson et al, Clin Cancer Res, 2007, 13, 3198-208; de Haas et al, Neoplasia, 2008, 10, 1041-8). Although apoptotic cells are typically cleared by phagocytes such as macrophages, it has been hypothesized that local clearance mechanisms are overloaded in cases of high cellular turnover and death, causing dying apoptotic cells to undergo secondary necrosis (Linder et al, Cancer Lett, 2004, 1, 1-9). While the plasma membrane remains intact during apoptosis, it is compromised and ruptured during secondary necrosis. Such secondary necrosis of dying tumor cells is consistent with the observation of what are normally intracellular components such as cytochrome c, DNA, nucleosomes, and cytokeratin-18 in the vasculature of cancer patients during chemotherapy (Beachy et al., Cancer Immunol Immunother, 2008, 57, 759-75).

A logical extension of these findings is that other caspase-derived neo-epitopes besides caspase-cleaved cytokeratin-18 are released into the vasculature of cancer patients undergoing chemotherapy. Such additional caspase-proteolyzed proteins may represent novel prognostic, diagnostic, or pharmacodynamic biomarkers of in vivo apoptosis, predicting likely patient outcome, indicating the most suitable therapeutic regimen, or serving as markers of therapeutic response. Because of tumor and patient heterogeneity, the clinical utility of single biomarker assays can be limited (Anderson et al., Mol Cell Proteomics, 2002, 1, 845-67). A multiparameter diagnostic assay of in vivo apoptosis based on a panel of caspase-derived neo-epitopes would likely be more sensitive and specific for a given type of cancer or therapeutic regimen. Great utility therefore exists in the identification of physiologically relevant caspase cleavage sites. Knowledge of such cleavage sites is required for the preparation of both peptide standards corresponding to neo-epitopes and antibodies that specifically bind to neo-epitopes. These reagents will enable identification and quantitation of caspase-derived neo-epitopes in biological samples such as serum, plasma, or tissue biopsies, and for validation of a given set of caspase-derived neo-epitopes as clinically useful biomarkers of in vivo apoptosis.

BRIEF SUMMARY OF THE INVENTION

The present invention relates generally to 1356 experimentally determined and physiologically relevant caspase-like cleavage sites, a method for discovering additional physiologically relevant caspase cleavage sites, discovery of biomarkers of in vivo apoptosis based on any of these caspase-like cleavage sites, and methods and compositions for detecting and quantitating protein neo-epitopes corresponding to these biomarkers in biological samples, using either peptide standards and mass spectrometry, or antibodies specific to neo-epitopes, or both. The invention also provides compositions and kits for performing the methods of the invention.

Direct and selective labeling of protein α-amines or α-carboxylates is a powerful approach for profiling proteolysis in complex mixtures since it permits direct identification of cleavage sites in protein substrates. Approximately 80% of mammalian proteins are known to be N-terminally acetylated (Brown et al., J Biol. Chem. 1976; 251(4):1009-14). Thus, greater signal over background can be achieved through N-terminal instead of C-terminal labeling. However, such labeling must still be extremely selective for α-amines over lysine ε-amines, which are approximately 25 times more abundant in an average protein. To achieve this selectivity, we have adopted an enzymological approach that makes use of the rationally designed protein ligase subtiligase. This engineered enzyme exhibits absolute selectivity for modification of α-amines (Abrahmsén et al., Biochemistry. 1991; 30(17):4151-9; Chang et al., Proc Natl Acad Sci USA. 1994; 91(26):12544-8).

We have developed a proteomic method utilizing subtiligase that enables capture and sequencing of N-terminal peptides found in complex biochemical mixtures (FIG. 1A). Proteins in biological samples are N-terminally biotinylated by treatment with subtiligase and peptide glycolate ester substrates specially tailored to our proteomic workflow (FIG. 1B).

Biotinylated samples are exhaustively digested with trypsin, and N-terminal peptides are captured using avidin affinity media. The peptide ester substrate contains a tobacco etch virus (TEV) protease cleavage site to permit facile recovery of captured peptides. An important aspect of our workflow is that recovered peptides retain an N-terminal serinyl-tyrosyl dipeptide modification or 2-aminobutyryl modification, providing a key hallmark to distinguish labeled peptides from contaminating unlabeled peptides using tandem mass spectrometry (LC/MS/MS). In standard protease nomenclature, substrates are cleaved between the P1 (N-terminal) and P1′ (C-terminal) residues, with Pn and Pn′ residues increasing in count by one in both directions away from the scissile bond (Schechter and Berger, 1968). Thus, the Pn′ residues of a cleavage site correspond to N-terminal residues of the labeled peptide identified, while the Pn residues of a cleavage site can be inferred from the protein sequence preceding the identified peptide.

Over 300 publications describing a wide variety of cell types and apoptotic inducers have reported the proteolysis of approximately 360 human proteins in apoptosis, but only approximately 300 caspase cleavage sites in human protein substrates have been reported (Lüthi et al., Cell Death Differ. 2007; 14(4):641-50). We have carried out studies in a number of cancer cell lines, including Jurkat, an acute lymphocytic leukemia cell line, DB, a diffuse large B cell lymphoma cell line, and RPMI 8228, a multiple myeloma cell line, using a variety of apoptotic inducers including etoposide, doxorubicin, staurosporine, and TRAIL. Our combined studies to date have resulted in the identification of approximately 1360 caspase cleavage sites in a approximately 1040 protein substrates. These caspase cleavage sites and additional caspase cleavage sites yet to be discovered in other model systems of human cancers represent a wealth of knowledge and an excellent starting point for discovery of novel biomarkers of in vivo apoptosis, and for preparation of reagents for detection and quantitation of such biomarkers in biological samples.

The present invention provides proteolytic polypeptide biomarkers for the detection and quantitation of apoptosis. In one embodiment of the invention, these biomarkers comprise proteolytic polypeptides generated in response to an apoptotic stimulus. The biomarkers of the present invention may be generated in response to a specific apoptotic stimulus or conversely may be generated by multiple or general apoptotic stimuli. In some embodiments, the proteolytic polypeptide biomarkers of the present invention are generated by the action of a single protease, or by the action of a limited set of proteases activated in response to a specific apoptotic stimulus. In other embodiments, the biomarkers may be generated by the action of a plurality of apoptotic proteases. In a particular embodiment, the proteolytic apoptotic polypeptide biomarkers comprise N-termini or C-termini selected from those found in Table 1.

In one embodiment, the proteolytic biomarkers of the present invention are useful for the detection of apoptosis in an individual. In a specific embodiment, the proteolytic biomarkers are useful for the diagnosis in an individual of a disease characterized by apoptosis. In another embodiment, these biomarkers are useful for providing a prognosis for an individual suffering from a disease characterized by apoptosis. In yet other embodiments, these biomarkers are useful for determining the extent of apoptosis in an individual or the severity, stage, or other relevant characteristics of a disease characterized by apoptosis in an individual. In one particular embodiment, the proteolytic apoptotic biomarkers of the present invention are useful in determining the efficacy of a drug in vitro or in vivo.

In another embodiment, the present invention provides novel proteolytic apoptotic cleavage junctions. In certain embodiments, these cleavage junctions comprise amino acids that are cleavage substrates for proteases activated in response to an apoptotic stimulus. In a particular embodiment, the proteolytic apoptotic cleavage junctions comprise an amino acid sequence selected from those found in Table 3. In a first embodiment, the cleavage junctions of the present invention are useful for detecting apoptosis in a biological sample. In a second embodiment, the cleavage junctions are useful for diagnosing or providing a prognosis for a disease state associated with apoptosis in an individual, or for assessing response to a particular line of therapy. For instance, a protein or polypeptide comprising the cleavage junction can be used in an assay to measure apoptotic protease (e.g., a caspase) activity or levels in a sample. The peptides or polypeptides comprising the junction may be of a variety of lengths, preferably from 7 to 40, 7 to 20, or 10 to 30 amino acids in length.

The present invention also provides proteolytic apoptotic signatures. In one embodiment, the apoptotic signatures of the invention comprise at least one proteolytic polypeptide generated in response to an apoptotic stimulus. In another embodiment of the invention, the apoptotic signatures comprise the levels of one or more proteolytic polypeptides. In a particular embodiment, the apoptotic signatures of the present invention comprise the presence or particular level of one or more proteolytic polypeptides comprising N-termini or C-termini selected from those found in Table 1. In yet other embodiments, the apoptotic signatures of the present invention may comprise one or more ratios of cleaved to uncleaved apoptotic proteolytic sites. In a particular embodiment of the present invention, the apoptotic proteolytic sites are selected from those found in Table 3. In some embodiments, the proteolytic apoptotic signatures of the present invention may correspond to the presence or absence of a disease state in an individual. In other embodiments of the present invention, the proteolytic apoptotic signatures may correspond to a particular level of apoptosis in an individual or in a sample from an individual suffering from a disease characterized by apoptosis. In another embodiment of the present invention, the proteolytic apoptotic signatures may correspond to a prognosis for an individual suffering from a disease characterized by apoptosis. In yet other embodiments, the apoptotic signatures may correspond to a level of efficacy for a drug or to a response level in an individual taking a drug or receiving a treatment for a disease characterized by apoptosis.

In one embodiment, the present invention provides reagents for detecting the proteolytic apoptotic polypeptide biomarkers of the invention. In one embodiment, the reagents comprise synthetic peptides corresponding to an N-terminal or C-terminal sequence selected from those found in Table 1. In a particular embodiment, these synthetic peptides have the same sequence as either an unmodified or modified peptide found in Table 1. In another embodiment, these synthetic peptides contain six or more consecutive residues from a sequence of previous residues found in Table 1, starting from the most C-terminal residue, and possibly extending to further than eight prior residues in the sequence of the full-length protein. In one embodiment, these peptides correspond to the most N-terminal peptide obtained after digestion with trypsin of the C-terminal fragment of the full-length protein following proteolysis during apoptosis at one the cleavage sites found in Table 2. In another embodiment, these peptides correspond to the most C-terminal peptide obtained after digestion with trypsin of the N-terminal fragment of the full-length protein following proteolysis during apoptosis at one the cleavage sites found in Table 1 or 2. In another embodiment, these peptides correspond to the peptides that would be obtained following digestion of the N- and C-terminal fragments of the protein substrate with a protease other than trypsin, including, but not limited to, chymotrypsin, V8, Lys-C, Lys-N, Arg-C, Asp-N, Asp-C, pepsin, and thermolysin. In another particular embodiment, these peptides correspond to the peptides that would be obtained following treatment of the N- and C-terminal fragments of the protein substrate with a chemical cleavage agent such as cyanogen bromide. In a specific embodiment, the synthetic peptides contain stable heavy isotopes of carbon or nitrogen (e.g., ¹³C or ¹⁵N), incorporated by use of the appropriately heavy isotope-labeled amino acid during preparation of the synthetic or modified peptides. In a particular embodiment, the light and heavy versions of the peptides are used as standards in a mass spectrometry approach such as selected reaction monitoring (SRM) or multiple reaction monitoring (MRM) to optimize detection of corresponding peptides in biological samples derived from proteolytic apoptotic polypeptides, and to permit quantitation of such peptides in biological samples.

In another embodiment, the present invention provides reagents for detecting the proteolytic apoptotic polypeptide biomarkers of the invention. In one embodiment, the reagents comprise proteins that bind to the biomarkers with high affinity and specificity. In a particular embodiment, the reagents comprise antibodies, or fragments thereof, generated against the proteolytic apoptotic polypeptides of the present invention. In a specific embodiment, the present invention provides antibodies that bind to a proteolytic apoptotic polypeptide comprising an N-terminal or C-terminal sequence selected from those found in Table 1. In one embodiment, an antibody of the present invention binds to the target proteolytic fragment, but does not substantially bind to the full-length protein or intact proteolytic cleavage junction. In other embodiments, the reagents comprise antibodies generated against antigens comprising apoptotic cleavage sites or junctions. In a specific embodiment, the present invention provides antibodies that bind to an apoptotic cleavage site selected from those listed in Table 3. In one embodiment, the antibodies of the present invention bind to an intact proteolytic cleavage junction, but do not substantially bind to the N-terminal or C-terminal proteolytic polypeptide generated in response to an apoptotic stimulus. In another particular embodiment of the invention, antibodies are provided that bind to the N-terminus or C-terminus of a proteolytic polypeptide comprising a sequence selected from those found in Table 1.

In another embodiment, the present invention provides methods of generating binding reagents to one or more proteolytic apoptotic polypeptide biomarker. In one embodiment of the invention, methods are provided for generating a binding reagent to a single proteolytic polypeptide. In other embodiments, the present invention provides methods of simultaneously generating binding reagents against more than one proteolytic polypeptides of the present invention. In a particular embodiment, the present invention provides methods of generating antibodies against one or more proteolytic apoptotic polypeptide of the invention.

In one embodiment, the present invention provides methods of detecting apoptosis or determining the level of apoptosis in an individual or in a sample from an individual. In one embodiment, the methods comprise detecting a proteolytic apoptotic polypeptide biomarker generated in response to an apoptotic stimulus in a biological sample. In certain embodiments, the methods of the present invention comprise detecting one or more biomarkers comprising an N-terminal or C-terminal sequence selected from those found in Table 1. In other embodiments of the present invention, methods are provided for detecting or determining a proteolytic apoptotic signature. In certain embodiments of the invention, detecting or determining a proteolytic apoptotic signature comprises detecting or determining the level of one or more proteolytic apoptotic polypeptide biomarkers generated in response to an apoptotic signature. In other embodiments, the methods further comprise comparing a first proteolytic apoptotic signature detected in an individual with a second apoptotic signature corresponding to a predetermined apoptotic level or disease state. In certain embodiments of the invention, said second apoptotic signature comprises an average or conglomerate apoptotic signature determined from samples taken from a plurality of individuals suffering from the same disease or disease state associated with apoptosis. In yet other embodiments, the methods of the present invention comprise determining the ratio of the levels of at least one proteolytic apoptotic polypeptide to the levels of at least one intact proteolytic cleavage junction.

In another embodiment, the present invention provides methods for diagnosing or providing a prognosis for a disease associated with apoptosis in an individual, or for tracking therapeutic progress in an individual. In some embodiments of the present invention, the methods comprise detecting one or more proteolytic apoptotic polypeptide biomarkers in a sample from said individual. In other embodiments, the methods of the present invention comprise detecting a proteolytic apoptotic signature in a sample from an individual. In particular embodiments, the methods of the present invention comprise comparing the level of one or more proteolytic apoptotic polypeptide or apoptotic signature in an individual with one or more proteolytic apoptotic signature corresponding to a predetermined disease or disease state. In yet other embodiments, the methods of diagnosing and providing a prognosis provided by the present invention comprise determining the ratio of the levels of at least one proteolytic apoptotic polypeptide to the levels of at least one intact proteolytic cleavage junction. In particular embodiments, these methods further comprise comparing said ratios to predetermined values corresponding to a particular diagnosis or prognosis for a disease state associated with apoptosis. In another embodiment, the methods comprise comparing levels of apoptotic signatures in a patient before the start of therapy, and during the course of therapy.

In one embodiment, the present invention provides kits for use in the detection of proteolytic apoptotic polypeptides. In some embodiments, the kits of the present invention comprise a plurality of light- or heavy-labeled synthetic peptides corresponding to N- and/or C-terminal sequences found in Table 1 that can be used for optimizing detection of corresponding peptides in biological samples derived from proteolytic apoptotic polypeptides, and to permit quantitation of such peptides in biological samples, using mass spectrometry. In other embodiments, the kits of the present invention comprise a plurality of binding reagents that specifically bind to proteolytic polypeptides that are generated in response to an apoptotic stimulus. In a specific embodiment, the kits of the present invention comprise a plurality of binding reagents that bind to polypeptides comprising an N-terminal or C-terminal sequence found in Table 1. In certain embodiments, the binding reagents are antibodies, including polyclonal antibodies, monoclonal antibodies, and fragments thereof. In certain embodiments, the kits of the present invention are useful in the diagnosis or prognosis of a disease characterized by apoptosis in an individual, or for tracking therapeutic progress in an individual that is characterized by an increased level of apoptosis. In yet other embodiments, the present invention provides kits comprising a plurality of binding reagents that specifically bind to proteolytic apoptotic cleavage junctions. In a particular embodiment, the proteolytic apoptotic cleavage junctions comprise amino acid sequences found in Table 3. In still other embodiments, the kits of the present invention comprise at least one binding reagent that specifically binds to a proteolytic apoptotic polypeptide and at least one binding reagent that specifically binds to a proteolytic apoptotic cleavage junction. In other certain embodiments, the kits comprise binding reagents that specifically bind to peptides generated from proteolytic apoptotic polypeptides after treatment with proteases such as trypsin, chymotrypsin, V8, Lys-C, Lys-N, Arg-C, Asp-N, Asp-C, pepsin, or thermolysin, or reagents such as cyanogen bromide, permitting enrichment of these peptides for detection and quantitation using mass spectrometry.

In another aspect, the invention provides a method of modulation apoptosis by administering a siRNA or a shRNA corresponding to an mRNA encoding a protein of Table 1. In this first aspect, the invention also provides a pharmaceutical composition comprising the siRNA molecule or the shRNA molecule and/or an siRNA or shRNA expression vector which comprises a portion of a nucleotide sequence complementary to an mRNA encoding a protein of Table 1. In some embodiments, the siRNA is at least about 15-50 nucleotides in length (e.g., each complementary sequence of the double stranded siRNA is 15-50 nucleotides in length, and the double stranded siRNA is about 15-50 base pairs in length). In some further embodiments still, the length of the siRNA molecule is about 20-30 base nucleotides, about 20-25 or about 24-29 nucleotides in length, e.g., 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, or 30 nucleotides in length. In still further embodiments, the siRNA is a small hairpin loop or small hairpin RNA, known as shRNA. In some embodiments, the invention provides a method of treating cancer or inducing apoptosis in a subject in need thereof by administering the siRNA or shRNA or siRNA vector or shRNA vector to the subject. In some embodiments of any of the above the siRNA or shRNA is directed toward a protein having a M value from Table 1 greater than 1, 2, 4, or 8. In other embodiments, siRNA corresponding to a protein of Table 1 or 3 having a plurality of such cleavage sites is used.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1. A subtiligase subtiligase-based method for positive selection of peptides corresponding to N-termini of proteins from complex mixtures. (A) Workflow for biotinylation of protein N-termini in complex mixtures using subtiligase and a biotinylated peptide ester that contains a TEV protease cleavage site, trypsinization of labeled proteins, capture of biotinylated N-terminal peptides with immobilized avidin, recovery of captured peptides using TEV protease, and analysis of N-terminal peptides by 1D or 2D LC/MS/MS for identification of corresponding proteins and cleavage sites. The representative MS/MS spectrum corresponds to semi-tryptic peptide GSAVNGTSSAETNLEALQK from MEK1 (MP2K1_HUMAN) (SEQ ID NO:178) and identifies a previously unknown caspase-like cleavage site at Asp 16. The a² and b₂ ions at m/z 223 and 251 are characteristic hallmarks of a ligated, serinyl-tyrosyl dipeptive-bearing, N-terminal peptide. (B) Structure of two biotinylated peptide glycolate esters used in the proteomic workflow. Sequences: SYGSAVNGTSSAETNLEALQK (SEQ ID NO:431); MEK1 protein sequence (SEQ ID NO:432); cleavage site (SEQ ID NO:433), Ester1 (SEQ ID NO:434), Ester2 (SEQ ID NO:435), TENLYFQSY (fragment of SEQ ID NO:434).

FIG. 2. Classification of unique N-termini identified in untreated and apoptotic Jurkat cells according to Swiss-Prot annotation. (A) Classification of N-termini identified in small-scale and large-scale experiments with untreated cells (131 and 661 unique N-termini, respectively, combined from two experiments in both cases). (B) Classification N-termini identified in small-scale experiments with untreated cells (131 unique N-termini combined from two experiments) and apoptotic cells (244 unique N-termini combined from four experiments). (C) Classification N-termini identified in large-scale experiments with untreated cells (661 unique N-termini combined from two experiments) and apoptotic cells (733 unique N-termini combined from three experiments).

FIG. 3. N-termini derived from caspase-like proteolytic processing are a hallmark of apoptotic cells. (A) Frequencies of P1 and P1′ amino acid residues corresponding to non-homologous N-termini identified in small-scale 1D LC/MS/MS experiments with untreated and apoptotic Jurkat cells. Data are represented as mean±SD (n=2 for untreated and n=4 for apoptotic). (B) Frequencies of P1 and P1′ amino acid residues corresponding to non-homologous N-termini identified in large-scale 2D LC/MS/MS experiments with untreated and apoptotic Jurkat cells. Data are represented as mean±SD (n=2 for untreated and n=3 for apoptotic). “-” indicates lack of a putative P1 residue in cases where the P1′ residue is an initiator methionine.

FIG. 4. Inferred P1 residues for all N-termini annotated in the human Swiss-Prot database originating from chain, signal peptide, transit peptide, or propeptide processing.

FIG. 5. Analysis of proteolysis of selected proteins, all identified as caspase substrates in proteomic studies, during apoptosis in Jurkat cells following treatment with 50 μM etoposide. Black arrows indicate full-length proteins. Red arrows indicate expected cleavage products for cleavage at the sites identified in our studies. Cleavage products were not detected in all cases. (A) Time courses for the proteolysis of CCTδ, HDAC6, HDAC7, Ku80, LCOR, N-CoR, RBBP7, RCOR2, SHARP, TBLR1, UBP5, and UBP36 indicates full cleavage of HDAC6, HDAC7, N-CoR, RCOR2, SHARP, TBLR1, UBP5, and UBP36, and partial cleavage of CCTδ, Ku80, LCOR, and RBBP7. (B) The cleavage of a representative set of substrates identified in our studies, HDAC7, Ku80, RCOR2, TBLR1, and UBP36, is blocked by the broad-spectrum caspase inhibitor Z-VAD(OMe)-fmk and is thus dependent on caspase activity.

FIG. 6. Substrate specificity of the caspase-like proteolytic activity in etoposide-treated Jurkat cells. (A) Sequence logo representation (Crooks et al., 2004) of the frequency of amino acid residues in the identified caspase cleavage sites. (B) Sequence logo representation of the in vitro substrate specificity of caspase-3 (Stennicke et al., 2000; Thornberry et al., 1997). (C) Sequence logo representation of the frequency of amino acid residues in known human and human ortholog of rodent caspase cleavage sites (Lüthi and Martin, 2007). (D) Frequency of P4-P1 motifs in the identified caspase cleavage sites. (E) Receiver operator characteristic curves showing the discrimination ability of HMMs constructed from three different cleavage site training sets (Jurkat, literature, and merged). Three representative HMM score threshold values for the merged dataset are indicates (TPR=true positive rate, FPR=false positive rate). Sequence: DEVD (SEQ ID NO:430).

FIG. 7. Sequence logo representations of prototypical inflammatory, executioner, and initiator caspase substrate specificities. These are exemplified by (A) caspase-1, (B) caspase-3, and (C) caspase-8, based on P4-P1 data adapted from Thornberry et al. (Thornberry et al., J Biol. Chem. 1997; 272(29):17907-11) and P1′ data adapted from Stennicke et al. (Stennicke et al., Biochem J. 2000; 350 Pt 2:563-8).

FIG. 8. CID spectrum of the SY-labeled N-terminal peptide AAASAPQM(Oxidation)DVSK from N-CoR (NCOR1_HUMAN) (SEQ ID NO:402) corresponding to the P4-P4′ cleavage site LVD(1826)/AAAS (SEQ ID NO:403).

FIG. 9. CID spectrum of the SY-labeled N-terminal peptide GLSEQENNEK from N-CoR (NCOR1_HUMAN) (SEQ ID NO:404) corresponding to the P4-P4′ cleavage site EIID(385)/GLSE (SEQ ID NO:405).

FIG. 10. CID spectrum of the SY-labeled N-terminal peptide GTAEETEEREQATPR from N-CoR (NCOR1_HUMAN) (SEQ ID NO:406) corresponding to the P4-P4′ cleavage site DKID(555)/GTAE (SEQ ID NO:407).

FIG. 11. CID spectrum of the SY-labeled N-terminal peptide GDVEIPPNKAVVLR from TBLR1 (TBL1R_HUMAN) (SEQ ID NO:408) corresponding to the P4-P4′ cleavage site MEVD(152)/GDVE (SEQ ID NO:409).

FIG. 12. CID spectrum of the SY-labeled homologous N-terminal peptide AVM(Oxidized)PDVVQTR from either TBLR1 (TBL1R_HUMAN) or TBL1X (TBL1X_HUMAN) (SEQ ID NO:410) corresponding to the P4-P4′ cleavage site SLID(86)/AVMP (SEQ ID NO:411).

FIG. 13. CID spectrum of the SY-labeled N-terminal peptide GGGPGQVVDDGLEHR from HDAC7 (HDAC7_HUMAN) (SEQ ID NO:412) corresponding to the P4-P4′ cleavage site LETD(412)/GGGP (SEQ ID NO:413).

FIG. 14. CID spectrum of the SY-labeled N-terminal peptide SIQEPVVLFHSR from SHARP (MINT_HUMAN) (SEQ ID NO:414) corresponding to P4-P4′ caspase-like cleavage site STTD(1574)/SIQE (SEQ ID NO:415).

FIG. 15. CID spectrum of the SY-labeled N-terminal peptide SDKGEFGGFGSVTGK from RBBP7 (RBBP7_HUMAN) (SEQ ID NO:416) corresponding to P4-P4′ caspase-like cleavage site SHCD(98)/SDKG (SEQ ID NO:417).

DETAILED DESCRIPTION OF THE INVENTION

The present invention provides novel proteolytic apoptotic polypeptide biomarkers. In one embodiment of the invention, the proteolytic apoptotic polypeptide biomarkers are generated in response to an apoptotic stimulus. In certain embodiments, the apoptotic stimulus may be endogenous to the cell, tissue, organ, or organism of interest. In other embodiments, the apoptotic stimulus may be exogenous or induced, such as in tissue culture. In some embodiments, apoptosis may be induced by the treatment of cells, tissues, organs, or organisms with a drug known to cause apoptosis, such as etoposide, camptothecin, anisomycin, and the like. In a specific embodiment, the proteolytic apoptotic polypeptide biomarkers of the present invention comprise N-terminal or C-terminal sequences selected from those found in Table 1.

In certain embodiments of the invention, the proteolytic apoptotic polypeptide biomarkers comprise proteolytic fragments that are generated by cleavage of a full length protein of Table 1 or an intact proteolytic apoptotic cleavage junction of Table 1 by the action of a suitable protease. Suitable proteases will be obvious to the skilled artisan. In one particular embodiment, the protease is an enzyme known to function in the apoptotic pathway of a cell such as a caspase. In one embodiment of the present invention, a proteolytic apoptotic polypeptide biomarker of the present invention will have a sequence selected from those found in Table 1 at its N-terminus or C-terminus. In some embodiments of any of the above the polypeptide biomarker corresponds to a protein having a M value from Table 1 of 1 or greater than 1, 2, 4, or 8. In other embodiments, the biomarker corresponds to a protein of Table 1 or 3 having a plurality of such apoptotic polypeptide biomarkers or cleavage sites. In yet another embodiment, a plurality of biomarkers from Table 1 are used in assessing apoptosis or a particular apoptosis pathway in which the biomarkers correspond to apoptotic cleavages of multiple protein substrates of a single apoptotic protease (e.g., caspase) of interest. In other embodiments, the biomarkers from Table 1 are selected so as to include biomarkers for the activity of a plurality of apoptotic proteases of interest.

In certain embodiments, a proteolytic apoptotic polypeptide biomarker of the invention may further comprise a recombinant sequence N-terminal or C-terminal to a sequence found in Table 1. For example, a biomarker of the invention may further comprise a fusion tag used to facilitate purification, detection, or both purification and detection of the polypeptide. Many fusion tags suitable for use with the present invention are well known in the art and include without limitation, polyhistidine tags, GST tags, biotin, calmodulin binding protein tags, chitin binding protein tags, TAP tags, Strep tags, Myc tags, HA tags, and the like. Other suitable recombinant sequences may further comprise a linker between the fusion tag and the polypeptide. Linker sequences may comprise a protease recognition site, such as a TEV cleavage site.

The present invention also provides proteolytic apoptotic cleavage junctions. In certain embodiments, a cleavage junction of the present invention may comprise an amino acid sequence targeted by a protease in response to an apoptotic stimulus. In a particular embodiment, the cleavage junctions of the present invention comprise sequences selected from those found in Table 3. In one embodiment, a cleavage junction of the invention comprises a full length protein containing a sequence identical to a sequence listed in Table 3. In a second embodiment, a cleavage junction of the present invention may comprise a protein fragment containing a sequence found in Table 3, that is competent for cleavage by a protease involved in apoptosis. In certain embodiments, the protein fragment may comprise about 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 125, 150, 175, 200, 250, 300, 400, 500, 600, 700, 800, 900, 1000, or more amino acids of a protein identified by a Swiss-Prot ID found in Table 3. In some embodiments, the peptide is preferably at least about 6 amino acids long, 7 amino acids long, 8 amino acids long, 10 amino acids long and less than 50 amino acids long and can comprise or consist of an amino acid sequence (previous amino acid or C-terminal amino acid sequence, unmodified or identified amino acid, or N-terminal amino acid sequence, modified identified amino acid sequence, or protein) of Table 1. Preferred peptides for measuring the activity of apoptotic protease include the cleavage junction corresponding to a previous amino acid sequence of Table 1 and its corresponding immediately following identified or unmodified peptide of Table 1. A preferred ranged of peptide lengths is from about 7 to 50 amino acids in length and may include the full sequences of both the previous and identified or unmodified polypeptides of Table 1. Other suitable lengths range from 7 to 25, 7 to 15, 10 to 30, 15 to 35, and 15 to 25.

The apoptotic biomarkers of the present invention find use in the detection and quantification of apoptosis in a biological sample. In certain embodiments, the biomarkers can be used to detect apoptosis in a sample from an organism suffering from a disease characterized by apoptosis. In one embodiment, the biomarkers of the present invention can be used to diagnose or provide a prognosis for a disease characterized by apoptosis in an individual. In other embodiments the biomarkers can be used to determine the extent of apoptosis or the extent of a disease state in an individual or in a sample from an individual. In yet other embodiments, the biomarkers of the present invention are useful for determining the efficacy of a drug or for monitoring treatment in a patient. The biomarkers are particularly useful for determining the efficacy of drugs that induce apoptosis or for monitoring a treatment in a patient that results in apoptosis.

In one embodiment, the present invention provides proteolytic apoptotic signatures or profiles. In a specific embodiment, the apoptotic signatures of the present invention comprise one or more proteolytic polypeptide that is generated in response to an apoptotic stimulus. In another embodiment, an apoptotic signature of the invention comprises the level of at least one proteolytic apoptotic polypeptide biomarker in a biological sample. In one specific embodiment of the invention, an apoptotic signature comprises the level of at least one, preferably at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 125, 150, 175, 200, 250, 300, or more proteolytic apoptotic polypeptides comprising an N-terminus or C-terminus selected from those found in Table 1, in a biological sample. In some embodiments, the N-terminus or C-terminus is that formed by the cleavage of a polypeptide by an apoptotic protease. In another embodiment of the invention, an apoptotic signature or profile comprises a plurality, or the level of a plurality, of proteolytic apoptotic cleavage junctions. In a specific embodiment, an apoptotic signature comprises the level of at least one, preferably at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 125, 150, 175, 200, 250, 300, or more proteolytic apoptotic cleavage junctions, in a biological sample, selected from those found in Table 3. In further embodiments of the present invention, a proteolytic apoptotic signature may comprise a mixture of proteolytic apoptotic polypeptides and proteolytic apoptotic cleavage junctions, or the levels thereof, in a biological sample. In yet another embodiment, a proteolytic apoptotic signature comprises one or more ratio of a proteolytic apoptotic polypeptide to its corresponding intact proteolytic apoptotic cleavage junction in a biological sample. For example, a proteolytic apoptotic signature of the present invention may comprise at least one, preferably at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 125, 150, 175, 200, 250, 300, or more ratios of cut to uncut proteolytic apoptotic cleavage junctions selected from those found in Table 3, or corresponding to the proteins identified by a Swiss-Prot ID found in Table 3, in a biological sample.

In certain embodiments, the present invention provides proteolytic apoptotic signatures that correspond to a specific level or degree of apoptosis in a biological sample, or in an individual. In other embodiments, the proteolytic apoptotic signatures of the present invention correspond to the level of apoptosis in a mammal suffering from a disease characterized by apoptosis. In yet other embodiments of the invention, a proteolytic apoptotic signature may correspond to a specific disease state or to a specific prognosis for a disease in an individual suffering with a disease characterized by apoptosis. In further embodiments, the proteolytic apoptotic signatures of the present invention may correspond to a specific efficacy for a drug administered to an individual or to a predicted response to a drug administered to an individual. The proteolytic apoptotic signatures of the present invention may be derived from a single biological sample from an individual or from a plurality of samples taken a group of individuals suffering from a disease characterized by apoptosis. In certain embodiments, the apoptotic signature may comprise an average of apoptotic signatures determined from a study or disease cohort.

In some embodiments, the present invention provides apoptotic signatures that correspond to healthy subjects, i.e. individuals that are not suffering from a disease, individuals that are suffering from a disease, individuals that have undergone therapy for a specific disease, individuals that have a good prognosis, individuals that have a bad prognosis, individuals with cancer, individuals with a high likelihood of developing metastatic cancer, individuals with a particular disease state, i.e. stage of cancer, severity of disease, benign tumor, and the like. As such, the various apoptotic signatures of the present invention find use in the diagnosis and prognosis of various diseases and disease states, as well as for monitoring the progression of a disease or the progression of a disease treatment regime.

In some embodiments, the invention provides synthetic peptides or polypeptides which are labeled with heavy isotopes of C, N, H, or O. For instance, ¹³C or ¹⁵N labeled peptides can be used as internal standards in the assay methods as known to one of ordinary skill in the art. By adding a known quantity of a heavy isotope-labeled peptide to a sample and then calculating the amount of the labeled polypeptide detected, it is possible to estimate the concentration of an unlabeled endogenous corresponding polypeptide in a sample by use of an analytical technique such as mass spectrometry (see, PCT Patent Publications WO 03026861 and WO 2008/054597), and see also, Carr et al., Clinical Chemistry 54:11 1749-1752 (2008) the contents of each of which are incorporated herein by reference in their entirety with respect to methods of quantitating proteins or polypeptides in a biological sample. Anderson et al., Journal of Proteome Research 2004, 3, 235-244; Carr et al., Nature Biotechnology 24(8):971 (2006); and Addona et al., Nature Biotechnology 27(7): 633 (2009); and McIntosh et al. Nature Biotechnology 27(7):622 (2009) are also each incorporated by reference in their entirety with respect to their disclosures of methods for detecting biomarkers in biological samples by targeted mass spectrometry. For instance, detection methods using selected reaction monitoring (SRM) or multiple reaction monitoring (MRM are contemplated.

An isotopically labeled peptide is preferably at least about 6 amino acids long, 7 amino acids long, 8 amino acids long, 10 amino acids long and less than 50 amino acids long and can comprise an amino acid sequence (previous amino acid or C-terminal amino acid sequence, identified or unmodified amino acid or N-terminal amino acid sequence, or the modified identified amino acid sequence of Table 1. Preferred labeled peptides for measuring the activity of apoptotic protease comprise a previous amino acid sequence of Table 1 with its corresponding immediately following identified or unmodified peptide of Table 1. A preferred ranged of labeled peptide lengths is from about 7 to 50 amino acids in length and may include the full sequences of both the previous and identified or unmodified polypeptides of Table 1.

The method detects and quantifies a target protein in a sample by introducing a known quantity of at least one heavy-isotope labeled peptide standard into a digested biological sample. By comparing to the peptide standard, one may readily determine the quantity of a peptide having the same sequence and protein modification(s) in the biological sample. Briefly, the methodology has two stages: (1) peptide internal standard selection and validation; method development; and (2) implementation using validated peptide internal standards to detect and quantify a target protein in a sample. The method is a powerful technique for detecting and quantifying a given peptide/protein within a complex biological mixture, such as a biological sample, a cell lysate, tissue section, or serum and may be used, e.g., to quantify change in protein as a result of drug treatment, or to quantify a protein in different biological states.

Generally, to develop a suitable internal standard, a particular peptide (or modified peptide) within a target protein sequence is chosen based on its amino acid sequence and a particular protease for digestion. The peptide can then generated by solid-phase peptide synthesis such that one residue is replaced with that same residue containing stable isotopes (e.g., ¹³C, ¹⁵N). The result is a peptide that is chemically identical to its native counterpart formed by proteolysis, but is easily distinguishable by MS via a mass shift. A newly synthesized internal standard peptide is then evaluated by the detection method. This process provides qualitative information about peptide retention by the detection method.

The second stage of the strategy is its implementation to measure the amount of a protein or the modified form of the protein from complex mixtures. A biological sample such as a cell lysate, tissue section lysate, or serum may be extensively digested with a protease such as trypsin. Labeled peptides can then be spiked in to the complex peptide mixture obtained by digestion of the biological sample with a proteolytic enzyme, either before or after an optional affinity purification of a subset of the peptides in the mixture, as described above. The retention time and fragmentation pattern of the native peptide formed by digestion (e.g., trypsinization) is identical to that 25 of the labeled internal standard peptide determined previously; thus, the use of isotopically labeled peptides results in the highly specific and sensitive measurement of both internal standard and analyte directly from extremely complex peptide mixtures. Because an absolute amount of the labeled peptide is added, the ratio of the amount of endogenous peptide detected to the amount of labeled peptide detected can be used to determine the precise levels of a polypeptide, or more specifically, a proteolytic apoptotic polypeptide, in a sample.

In addition, the internal or labeled polypeptide standard when present during digestion and chromatography, such that peptide extraction efficiencies and absolute losses during sample handling (including vacuum centrifugation), and variability during introduction into the detection system do not affect the determined ratio of native and labeled polypeptide abundances.

A peptide sequence within a target protein is selected according to one or more criteria to optimize the use of the peptide as an internal standard. Preferably, the size of the peptide is selected to minimize the chances that the peptide sequence will be repeated elsewhere in other non-target proteins. Thus, a peptide is preferably at least about 6 amino acids. The size of the peptide is also optimized to maximize ionization frequency. Thus, peptides longer than about 20 amino acids are not preferred. The preferred ranged is about 7 to 15 amino acids. A peptide sequence is also selected that is not likely to be chemically reactive during mass spectrometry, thus sequences comprising cysteine, tryptophan, or methionine are avoided.

The peptide is labeled using one or more labeled amino acids (i.e. the label is an actual part of the peptide) or less preferably, labels may be attached after synthesis according to standard methods. Preferably, the label is a mass-altering label selected based on the following considerations: The mass should be unique to shift fragment masses produced by MS analysis to regions of the spectrum with low background; the ion mass signature component is the portion of the labeling moiety that preferably exhibits a unique ion mass signature in MS analysis; the sum of the masses of the constituent atoms of the label is preferably uniquely different than the fragments of all the possible amino acids. As a result, the labeled amino acids and peptides are readily distinguished from unlabeled ones by the ion/mass pattern in the resulting mass spectrum. Preferably, the ion mass signature component imparts a mass to a protein fragment that does not match the residue mass for any of the 20 natural amino acids.

The label should be robust under the fragmentation conditions of MS and not undergo unfavorable fragmentation. Labeling chemistry should be efficient under a range of conditions, particularly denaturing conditions, and the labeled tag preferably remains soluble in the MS buffer system of choice. The label preferably does not suppress the ionization efficiency of the protein and is not chemically reactive. The label may contain a mixture of two or more isotopically distinct species to generate a unique mass spectrometric pattern at each labeled fragment position. Stable isotopes, such as ¹³C, ¹⁵N, ¹⁷O, ¹⁸O, or ³⁴S, are among preferred labels. Pairs of peptide internal standards that incorporate a different isotope label may also be prepared.

Peptide internal standards are characterized according to their mass-to-charge (m/z) ratio, and preferably, also according to their behavior in chromatographic columns (e.g. an HPLC column). Internal standards that co-elute with unlabeled peptides of identical sequence are selected as optimal internal standards. The internal standard can then analyzed be fragmenting the peptide by any suitable means, for example by collision-induced dissociation (CID) using, e.g., argon or helium as a collision gas. The fragments can then be analyzed, for example, by multi-stage mass spectrometry (MS^(n)) to obtain a fragment ion spectrum, to obtain a peptide fragmentation signature. Preferably, peptide fragments have significant differences in m/z ratios to enable peaks corresponding to each fragment to be well separated, and a signature that is unique for the target peptide is obtained. If a suitable fragment signature is not obtained at the first stage, additional stages of MS are performed until a unique signature is obtained.

Fragment ions in the MS/MS and MS spectra are typically highly specific for the peptide of interest, and, in conjunction with LC methods, allow a highly selective means of detecting and quantifying a target peptide/protein in a complex protein mixture, such as a cell lysate, containing many thousands or tens of thousands of proteins. Any biological sample potentially containing a target protein/peptide of interest may be assayed. Crude or partially purified cell extracts are preferably used. Generally, the sample may have at least 0.01 mg of protein, typically a concentration of 0.1-10 mg/mL, and may be adjusted to a desired buffer concentration and pH.

Accordingly, internal peptide standards (heavy-isotope or light isotope labeled peptides) may be produced, as described above, for any of the novel polypeptides of the invention (see Table 1). These peptides may then be further used in assessing apoptotic enzyme activities in samples as described herein.

Quantitation of Corresponding Peptides Derived from the Neo-Epitopes in Samples.

In one embodiment, the present invention provides reagents for detecting the proteolytic apoptotic polypeptide biomarkers of the invention. In one embodiment, the reagents comprise proteins that bind to the biomarkers with high affinity and specificity. In another embodiment, the invention provides binding reagents for detecting proteolytic apoptotic cleavage junctions. In a particular embodiment, the reagents comprise antibodies, or fragments thereof, generated against the proteolytic apoptotic polypeptides or proteolytic apoptotic cleavage junctions of the present invention. Suitable antibody fragment types include without limitation, F(ab′)2, F(ab), Fv, scFv, and the like. Antibodies can be generated by a number of well known methods including, without limitation, animal immunization, molecular display techniques, including phage display and ribosomal or mRNA display, rational design, and the like. In certain embodiments of the present invention, the binding reagents further comprise a detectable moiety and/or a tag to facilitate purification of the binding reagent or binding reagent-biomarker complex.

In another embodiment, the present invention provides methods for generating binding reagents to one or more apoptotic biomarkers. In certain embodiments the apoptotic biomarkers comprise N-terminal or C-terminal sequences selected form those found in Table 3. In other embodiments, the apoptotic biomarkers comprise cleavage junctions selected from those found in Table 3. In a specific embodiment, the methods of the present invention comprise the steps of: (a) generating a plurality of proteolytic apoptotic polypeptides; (b) generating one or more binding reagents to said plurality of proteolytic apoptotic polypeptides; and (c) purifying at least one of said binding reagents. Pluralities of proteolytic apoptotic polypeptides can be generated, for example, by heterologous gene expression, in vitro translation, synthetic peptide synthesis, purification of proteolytic polypeptides from a biological sample, or in vitro proteolysis of peptides containing a proteolytic apoptosis cleavage junction. In one embodiment, the binding reagents comprise proteins or antibodies that specifically bind to either a proteolytic apoptotic polypeptide or to an intact cleavage junction corresponding to a proteolytic apoptotic polypeptide, but do not substantially bind to both.

In certain embodiments, the methods of the present invention for generating one or more antibodies comprise the steps of (a) simultaneously immunizing a mammal with a plurality of apoptotic proteolytic polypeptides; (b) collecting the immune serum from said mammal; (c) affinity purifying a first antibody to a first proteolytic polypeptide, (d) affinity purifying at least a second antibody to at least a second proteolytic polypeptide from the supernatant of step (c), (e) removing antibodies that bind to the cleavage junction corresponding to said first proteolytic polypeptide by affinity means from said first antibody purification, and (f) removing antibodies that bind to the cleavage junction corresponding to said at least second proteolytic polypeptide by affinity means from said second antibody purification, thereby generating at least two antibodies to proteolytic apoptotic polypeptides. These methods find use in generating a plurality of antibodies that bind to a proteolytic apoptotic polypeptide, but that do not substantially bind to the cleavage junction corresponding to said proteolytic polypeptide. In certain embodiments, the methods can be altered in order to generate a plurality of antibodies that bind to a proteolytic apoptotic cleavage junction, but that do not substantially bind to the corresponding proteolytic polypeptides generated in response to an apoptotic stimulus. In further embodiments, the methods of the present invention can be performed using molecular display techniques.

In yet other embodiments, the present invention provides methods of generating an antibody to the N-terminus or C-terminus of a proteolytic polypeptide, the method comprising the steps of: (a) Generating the N-terminal or C-terminal apoptotic product, by means of heterologous gene expression, in vitro transcription-translation, or synthetic methods, or by producing the full length protein and cleaving it with a protease to generate the N-terminal and C-terminal pieces and purification of the N-terminal proteolytic fragment, C-terminal proteolytic fragment, or any combination thereof; (b) using the N-terminal or C-terminal apoptotic fragment to generate one or more antibodies, either by immunization of animal, or in vitro selection methods such as phage display, ribosome display or other suitable display or selection methods, or to generate other suitable binding protein or proteins, either by in vitro selection methods such as phage display, ribosome display or other suitable display or selection methods

The present invention also provides methods of detecting proteolytic apoptotic biomarkers, including both proteolytic apoptotic polypeptides and proteolytic apoptotic cleavage junctions, in a biological sample. In one embodiment, the method comprises contacting a biological sample with a binding reagent that specifically binds to a proteolytic apoptotic biomarker of the present invention and detecting the binding reagent, thereby detecting the biomarker. In a second embodiment, the present invention provides methods of quantitating the amount of a proteolytic apoptotic biomarker in a biological sample, the method comprising the steps of contacting a biological sample with a binding reagent of the present invention, and determining the amount of biomarker is said sample. Methods of detecting and quantitating the amount of a polypeptide in a sample are well known in the art and include, without limitation, ELISA, immunohistochemical techniques, mass spectrometry, Luminex® xMAP technology, and the like.

In another embodiment, the present invention provides methods of detecting apoptosis in an individual. In one embodiment, the methods comprise detecting at least one proteolytic apoptotic polypeptide in a biological sample from an individual. In another specific embodiment, the methods comprise detecting an increased ratio of the level of at least a first proteolytic apoptotic polypeptide biomarker to the level of at least one first proteolytic apoptotic cleavage junction biomarker that corresponds to said first proteolytic apoptotic polypeptide. In some embodiments, the present methods comprise the detection or quantitation of at least about 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100, 125, 150, 175, 200, 250, 300, or more proteolytic apoptotic biomarkers of the present invention, or corresponding ratios thereof. In a second embodiment, the methods of the present invention comprise the detection of a proteolytic apoptotic signature in a biological sample from an individual, thereby detecting the presence of apoptosis is said individual. In yet another embodiment, the present invention provides methods of detecting a proteolytic apoptotic signature in a subject, the methods comprising the steps of: (a) determining the level of at least two proteolytic polypeptides in a biological sample from said subject; and (b) comparing said levels of at least two proteolytic polypeptides to a proteolytic apoptotic signature, thereby detecting a proteolytic signature in the subject, wherein said at least two proteolytic polypeptides comprise N-terminal or C-terminal sequences selected from those found in Table 1.

In one embodiment, the present invention provides methods of determining the level of apoptosis in an individual. In a particular embodiment, the methods comprise the steps of: (a) determining the level of at least one proteolytic polypeptide that is generated in response to an apoptotic stimulus in a biological sample from said subject; and (b) comparing said level of at least one proteolytic polypeptide to a biological signature corresponding to no apoptosis, thereby determining the level of apoptosis in the subject, wherein said at least one proteolytic polypeptide comprises an N-terminal or C-terminal sequence selected from those found in Table 1. In a related embodiment, the method further comprises the step of (c) comparing said level of at least one proteolytic polypeptide to at least one biological signature corresponding to a predetermined level of apoptosis. In a second embodiment, the methods comprise the steps of: (a) determining the level of at least one intact proteolytic apoptotic cleavage junction in a biological sample from said subject; (b) determining the level of at least one of the N-terminal or C-terminal proteolytic polypeptides corresponding to said at least one intact proteolytic apoptotic cleavage junction in said biological sample; and (c) determining the ratio of proteolytic polypeptides to intact proteolytic apoptotic cleavage junctions in said biological sample, thereby determining the level of apoptosis in the subject, wherein said proteolytic polypeptides are generated in response to an apoptotic stimulus.

In another embodiment, the invention provides methods of diagnosing or providing a prognosis for a disease characterized by apoptosis in an individual. In a specific embodiment, the methods comprise the steps of: (a) detecting a first proteolytic apoptotic signature in a biological sample from said individual; and (b) comparing said first proteolytic apoptotic signature to at least a second proteolytic apoptotic signature corresponding to a diagnosis or prognosis for a disease characterized by apoptosis, thereby diagnosing or providing a prognosis for a disease characterized by apoptosis in said individual. In other embodiments, the methods further comprise the steps of: (c) comparing said first apoptotic signature to at least a third apoptotic signature corresponding to a diagnosis of no disease or a second prognosis for said disease; and (d) determining which apoptotic signature said first apoptotic most highly correlates to, thereby diagnosing or providing a prognosis for a disease characterized by apoptosis in said individual.

Many correlation methodologies may be employed for the comparison of both individual proteolytic apoptotic biomarker levels and proteolytic apoptotic signatures or profiles in the present invention. Non-limiting examples of these correlation methods include parametric and non-parametric methods as well as methodologies based on mutual information and non-linear approaches. Examples of parametric approaches include without limitation, Pearson correlation (or Pearson r, also referred to as linear or product-moment correlation) and cosine correlation. Non-limiting examples of non-parametric methods include Spearman's R (or rank-order) correlation, Kendall's Tau correlation, and the Gamma statistic. Each correlation methodology can be used to determine the level of correlation between the levels or ratios of individual biomarkers in the data set. The correlation of all biomarkers with all other biomarkers is most readily considered as a matrix. Using Pearson's correlation as a non-limiting example, the correlation coefficient r in the method is used as the indicator of the level of correlation. When other correlation methods are used, the correlation coefficient analogous to r may be used, along with the recognition of equivalent levels of correlation corresponding to r being at or about 0.25 to being at or about 0.5. The correlation coefficient may be selected as desired to reduce the number of correlated biomarkers to various numbers. In particular embodiments of the invention using r, the selected coefficient value may be of about 0.25 or higher, about 0.3 or higher, about 0.35 or higher, about 0.4 or higher, about 0.45 or higher, or about 0.5 or higher.

In another embodiment, the present invention provides methods of monitoring the progression of therapy for a disease in an individual. In certain embodiments, the methods comprise determining the level of a proteolytic apoptotic biomarker or an apoptotic signature at different time points in a sample from an individual undergoing therapy for a disease. In some embodiments, the method will comprise comparing the levels of biomarkers or signatures at different times during the course of a disease treatment. Typically, a disease that is characterized by increased apoptosis, such as auto-imune diseases, will result in a decrease in apoptosis, as measured by the levels of biomarkers or signatures in a biological sample from an individual, during the course of a successful treatment regime. Conversely, a disease that is characterized by decreased apoptosis, such as cancer, will typically result in increased apoptosis, as measured by the levels of biomarkers or signatures in a biological sample from an individual, during the course of a successful treatment regime. In this fashion a biological sample from a patient that is responding favorably to a treatment regime will show a change, either increase or decrease, in the level of apoptosis over time, as measured by the methods of the present invention. In a particular embodiment, the methods of the present invention are useful for monitoring the progression of cancer therapy in an individual. The methods of the invention are compatible with all types of cancer therapy including, without limitation, chemotherapy, hormone therapy, biologic therapy, radiation therapy, surgical therapy, and the like.

In one embodiment, the present invention provides methods of determining the efficacy of a drug. In a specific embodiment, the methods comprise the steps of: (a) determining the level of at least one proteolytic polypeptide generated in response to an apoptotic stimulus in a biological sample from a first subject receiving a dose of said drug; (b) determining the level of at least one proteolytic polypeptide generated in response to an apoptotic stimulus in a biological sample from a second subject not receiving a dose of said drug; and (c) comparing said first and said second levels of said at least one proteolytic polypeptide, thereby determining the efficacy of said drug, wherein said at least one proteolytic polypeptide comprises an N-terminal or C-terminal sequence selected from those found in Table 1. In yet other embodiments of the invention, the method comprises determining a proteolytic apoptotic signature and comparing said signature to a second proteolytic apoptotic signature corresponding to a specific level of apoptosis. Drugs particularly well suited for use with the above methods include both drugs that induce apoptosis and anti-apoptotic drugs.

Many pharmaceuticals are known to cause apoptosis in vivo including, without limitation, nonsteroidal anti-inflammatory drugs (NSAIDs) (Yamazaki et al., Journal of Pharmacology and Experimental Therapeutics 302(1): 18-25 (2002)) and chemotherapeutic drugs. Examples of NSAIDs include, without limitation, Salicylates (including Acetylsalicylic acid (Aspirin), Amoxiprin Benorylate/Benorilate, Choline magnesium salicylate, Diflunisal, Ethenzamide, Faislamine, Methyl salicylate, Magnesium salicylate, Salicyl salicylate, and Salicylamide), Arylalkanoic acids (including Diclofenac, Aceclofenac, Acemetacin, Alclofenac, Bromfenac, Etodolac, Indometacin, Nabumetone, Oxametacin, Proglumetacin, Sulindac, and Tolmetin), 2-Arylpropionic acids (profens) (including Ibuprofen, Alminoprofen, Benoxaprofen, Carprofen, Dexibuprofen, Dexketoprofen, Fenbufen, Fenoprofen, Flunoxaprofen, Flurbiprofen, Ibuproxam, Indoprofen, Ketoprofen, Ketorolac, Loxoprofen, Naproxen, Oxaprozin, Pirprofen, Suprofen, and Tiaprofenic acid), N-Arylanthranilic acids (fenamic acids) (including Mefenamic acid, Flufenamic acid, Meclofenamic acid, and Tolfenamic acid), Pyrazolidine derivatives (including Phenylbutazone, Ampyrone, Azapropazone, Clofezone, Kebuzone, Metamizole, Mofebutazone, Oxyphenbutazone, Phenazone, Phenylbutazone, and Sulfinpyrazone), Oxicams (including Piroxicam, Droxicam, Lornoxicam, Meloxicam, and Tenoxicam), COX-2 inhibitors (including Celecoxib, Etoricoxib, Lumiracoxib, Parecoxib, Rofecoxib, Valdecoxib), Sulphonanilides including Nimesulide, histone deacetylase inhibitors (including Trichostatin A, cyclic tetrapeptides, benzamides, electrophilic ketones, phenylbutyrate, valproic acid, SAHA (approved by the FDA in 2007 for leukemia therapy under the name Vorinostat), Belinostat/PXD101, MS275, LAQ824/LBH589, CI994, MGCD0103 (Beckers et al., Int. J. Cancer 121(5): 1138-48 (2007)) nicotinamide, dihydrocoumarin, naphthopyranone, 2-hydroxynaphaldehydes, and the like). While not all NSAIDs induce apoptosis, one of skill in the art will know which drugs are appropriate for use in the present invention. Drugs that do not induce apoptosis, including some NSAIDs and some chemotherapeutic agents, may be used in combination with other drugs that do induce apoptosis in certain embodiments of the present invention.

Examples of chemotherapeutic anti-cancer drugs include, without limitation, Aminopterin, Methotrexate, Pemetrexed, Raltitrexed, Cladribine, Clofarabine, Fludarabine, Mercaptopurine, Pentostatin, Thioguanine, Cytarabine, Decitabine, Fluorouracil/Capecitabine, Floxuridine, Gemcitabine, Sapacitabine, Chlorambucil, Chlormethine, Cyclophosphamide, Ifosfamide, Melphalan, Bendamustine, Trofosfamide, Uramustine, Carmustine, Fotemustine, Lomustine, Nimustine, Prednimustine, Ranimustine, Semustine, Streptozocin, Carboplatin, Cisplatin, Nedaplatin, Oxaliplatin, Triplatin tetranitrate, Satraplatin, Busulfan, Mannosulfan, Treosulfan, Procarbazine, Dacarbazine, Temozolomide, Carboquone, ThioTEPA, Triaziquone, Triethylenemelamine, Docetaxel, Larotaxel, Ortataxel, Paclitaxel, Tesetaxel, Vinblastine, Vincristine, Vinflunine, Vindesine, Vinorelbine, Ixabepilone, Aclarubicin, Daunorubicin, Doxorubicin, Epirubicin, Idarubicin, Amrubicin, Pirarubicin, Mitoxantrone, Pixantrone, Valrubicin, Zorubicin, Actinomycin, Bleomycin, Mitomycin, Plicamycin, Hydroxyurea, Camptothecin, Topotecan, Irinotecan, Rubitecan, Belotecan, Etoposide, Teniposide, Altretamine, Amsacrine, Bexarotene, Estramustine, Irofulven, Trabectedin, Cetuximab, Panitumumab, Trastuzumab, Rituximab, Tositumomab, Alemtuzumab, Bevacizumab, Edrecolomab, Gemtuzumab, Axitinib, Bosutinib, Cediranib, Dasatinib, Erlotinib, Gefitinib, Imatinib, Lapatinib, Lestaurtinib, Nilotinib, Semaxanib, Sorafenib, Sunitinib, Vandetanib, Alvocidib, Seliciclib, Aflibercept, Denileukin diftitox, Aminolevulinic acid, Efaproxiral, Methyl aminolevulinate, Porfimer sodium, Temoporfin, Verteporfin, Alitretinoin, Tretinoin, Anagrelide, Arsenic trioxide, Pegaspargase, Atrasentan, Bortezomib, Carmofur, Celecoxib, Demecolcine, Elesclomol, Elsamitrucin, Etoglucid, Lonidamine, Lucanthone, Masoprocol, Mitobronitol, Mitoguazone, Mitotane, Oblimersen, Omacetaxine, Sitimagene ceradenovec, Testolactone, Tiazofurine, Tipifarnib, and the like. While not all chemotherapeutic drugs induce apoptosis, one of skill in the art will know which drugs are appropriate for use in the present invention.

The invention also provides RNA interference, or RNAi, by use of siRNA or shRNA molecules directed toward a protein of Table 1. An “siRNA” or “shRNA” refers to a nucleic acid that forms a double stranded RNA, which double stranded RNA has the ability to reduce or inhibit expression of a gene or target gene when the siRNA expressed in the same cell as the gene or target gene. “siRNA” or “shRNA” thus refers to the double stranded RNA formed by the complementary strands. The complementary portions of the siRNA that hybridize to form the double stranded molecule typically have substantial or complete identity. In one embodiment, an siRNA refers to a nucleic acid that has substantial or complete identity to a target gene and forms a double stranded siRNA. Typically, the siRNA is at least about 15-50 nucleotides in length (e.g., each complementary sequence of the double stranded siRNA is 15-50 nucleotides in length, and the double stranded siRNA is about 15-50 base pairs in length, preferable about preferably about 20-30 base nucleotides, preferably about 20-25 or about 24-29 nucleotides in length, e.g., 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, or 30 nucleotides in length. The siRNA find use in moulating apoptosis, treating cancer by promoting apoptosis, and in treating conditions in which the modulation or promotion of apoptosis would be beneficial, or in treating disease or conditions characterized by apoptosis. The subjects are preferably human.

The design and making of siRNA molecules and vectors are well known to those of ordinary skill in the art. For instance, an efficient process for designing a suitable siRNA is to start at the AUG start codon of the mRNA transcript and scan for AA dinucleotide sequences (see, Elbashir et al. EMBO J. 20: 6877-6888 (2001). Each AA and the 3′ adjacent nucleotides are potential siRNA target sites. The length of the adjacent site sequence will determine the length of the siRNA. For instance, 19 adjacent sites would give a 21 nucleotide long siRNA siRNAs with 3′ overhanging UU dinucleotides are often the most effective. This approach is also compatible with using RNA pol III to transcribe hairpin siRNAs. RNA pol III terminates transcription at 4-6 nucleotide poly(T) tracts to create RNA molecules having a short poly(U) tail. However, siRNAs with other 3′ terminal dinucleotide overhangs can also effectively induce RNAi and the sequence may be empirically selected. For selectivity, target sequences with more than 16-17 contiguous base pairs of homology to other coding sequences can be avoided by conducting a BLAST search (see, www.ncbi.nlm.nih.gov/BLAST).

The siRNA or shRNA can be administered directly or an siRNA or shRNA expression vector can be used to induce RNAi. A vector can have inserted two inverted repeats separated by a short spacer sequence and ending with a string of T's which serve to terminate transcription. The expressed RNA transcript is predicted to fold into a short hairpin shRNA. The selection of shRNA target sequence, the length of the inverted repeats that encode the stem of a putative hairpin, the order of the inverted repeats, the length and composition of the spacer sequence that encodes the loop of the hairpin, and the presence or absence of 5′-overhangs, can vary. A preferred order of the shRNA expression cassette is sense strand, short spacer, and antisense strand. shRNAs with these various stem lengths (e.g., 15 to 30) are suitable. The length of the loops linking sense and antisense strands of the shRNA can have varying lengths (e.g., 3 to 9 nucleotides, or longer), The vectors may contain promoters and expression enhancers or other regulatory elements which are operably linked to the nucleotide sequence encoding the shRNA.

The expression “control sequences” refers to DNA sequences necessary for the expression of an operably linked coding sequence in a particular host organism. The control sequences that are suitable for prokaryotes, for example, include a promoter, optionally an operator sequence, and a ribosome binding site. Eukaryotic cells are known to utilize promoters, polyadenylation signals, and enhancers. These control elements may be designed to allow the clinician to turn of or on the expression of the gene by adding or controlling external factors to which the regulatory elements are responsive.

In yet another embodiment, the present invention provides kits for detecting or quantitating the biomarkers of the present invention. In certain embodiments, these kits comprise binding reagents, such as antibodies or proteins, that specifically bind the biomarkers of the invention. In other embodiments, the kits of the present invention comprise protein binding arrays for the detection or quantitation of the biomarkers of the invention. In one embodiment, the kits of the present invention are useful in the detection or quantitation of apoptosis in a biological sample. In a second embodiment, the kits of the invention are useful for diagnosing or for providing a prognosis for a disease characterized by apoptosis in an individual.

The present invention also provides novel enzymatic approaches for positive selection of protein fragments containing unblocked α-amines, characteristically produced in proteolysis. This approach makes use of an engineered peptide ligase termed subtiligase to selectively biotinylate unblocked protein α-amines in complex samples with great selectivity over E-amines of lysine side chains. Site-specific biotinylation permits subsequent purification and identification of corresponding N-terminal peptides using tandem mass spectrometry (LC/MS/MS).

The present invention provides a proteomic workflow utilizing subtiligase that enables biotinylation of protein α-amines in complex mixtures and subsequent cataloguing of N-termini in a given sample (FIG. 1A). Detergent lysates of either normal or apoptotic cells are first prepared in the presence of protease inhibitors to quench all protease activity. Proteins in these lysates are then N-terminally biotinylated by treatment with subtiligase and a peptide glycolate ester substrate specially tailored to the proteomic workflow (FIG. 1B). Biotinylated samples are then exhaustively digested with trypsin, and N-terminal peptides are captured using avidin affinity media. The peptide ester substrate contains a tobacco etch virus (TEV) protease cleavage site between biotin and the site of ligation to permit facile recovery of captured peptides (Rigaut et al., 1999). An important aspect of the workflow is that all labeled peptides recovered using TEV protease retain an N-terminal SY-dipeptide modification. This modification provides a key hallmark to distinguish ligated peptides from contaminating unligated ones using LC/MS/MS. Identification of recovered SY-peptides permits identification of corresponding proteins, native N-termini, and localization of proteolytic processing sites.

DEFINITIONS

“Subtiligase” refers generally to proteins which have the enzymatic activity of being able to ligate esterified peptides site-specifically onto the N termini of proteins or peptides. An example of such a subtiligase is one derived from the enzyme subtilisin BPN′ by site directed mutagenesis to effect the double substitution Ser221Cys and Pro225Ala, as described herein. Also described herein are additional subtiligases which have been engineered to exhibit other advantageous features, such as enhanced stability.

A “substrate” used in the context of subtiligase refers generally to any chemical moiety that is capable of being utilized during the enzymatic action of subtiligase that results in the specific labeling of the N termini of proteins or peptides by subtiligase. Examples of such substrates include peptide esters as described in greater detail herein.

“A complex mixture” refers generally to any composition that is composed of at least two or more proteins or peptides containing α-amines. A complex mixture can have at least two different proteins encoded by different genes; a complex mixture can be naturally occurring (e.g., a cell extract) or prepared (e.g., a formulation); a complex mixture can have recombinant, synthetic, or naturally occurring proteins or a mixture thereof. In many cases, a complex sample is one which displays a high degree of heterogeneity of proteins or peptides. Examples of complex mixtures include whole cells, cell extracts, partially purified cell extracts, tissues, bodily fluids, and animals, among others. Accordingly, in some embodiments, such complex mixtures comprise the naturally occurring proteins found in cells and tissues encoded by, for instance, different genes as found in the genomes of the source of the complex mixture (e.g., a cell or tissue extract or a bodily fluid such as serum). However, a complex mixture can also contain, as a component thereof, a recombinant protein or a purified protein or polypeptide either as an endogenous component (in the case of a recombinant protein), or as one added exogenously to the composition.

The term “recombinant” when used with reference, e.g., to a cell, or nucleic acid, protein, or vector, indicates that the cell, nucleic acid, protein or vector, has been modified by the introduction of a heterologous nucleic acid or protein or the alteration of a native nucleic acid or protein, or that the cell is derived from a cell so modified. Thus, for example, recombinant cells express genes that are not found within the native (non-recombinant) form of the cell or express native genes that are otherwise abnormally expressed, under expressed or not expressed at all.

The term “heterologous” when used with reference to portions of a nucleic acid indicates that the nucleic acid comprises two or more subsequences that are not found in the same relationship to each other in nature. For instance, the nucleic acid is typically recombinantly produced, having two or more sequences from unrelated genes arranged to make a new functional nucleic acid, e.g., a promoter from one source and a coding region from another source. Similarly, a heterologous protein indicates that the protein comprises two or more subsequences that are not found in the same relationship to each other in nature (e.g., a fusion protein).

A “cleavable linker” when used in the context of a peptide ester of the present invention refers generally to any element contained within the peptide that can serve as a spacer and is labile to cleavage upon suitable manipulation. Accordingly, a cleavable linker may comprise any of a number of chemical entities, including amino acids, nucleic acids, or small molecules, among others. A cleavable linker may be cleaved by, for instance, chemical, enzymatic, or physical means. Non-limiting examples of cleavable linkers include protease cleavage sites and nucleic acid sequences cleaved by nucleases. Further, a nucleic acid sequence may form a cleavable linker between multiple entities in double stranded form by complementary sequence hybridization, with cleavage effected by, for instance, application of a suitable temperature increase to disrupt hybridization of complementary strands. Examples of chemical cleavage sites include the incorporation photolabile, acid-labile, or base-labile functional groups into peptides.

“Proteases” (or “proteinases”, “peptidases”, or “proteolytic” enzymes) generally refer to a class of enzymes that cleave peptide bonds between amino acids of proteins. Because proteases use a molecule of water to effect hydrolysis of peptide bonds, these enzymes can also be classified as hydrolases. Six classes of proteases are presently known: serine proteases, threonine proteases, cysteine proteases, aspartic acid proteases, metalloproteases, and glutamic acid proteases (see, e.g., Barrett A. J. et al. The Handbook of Proteolytic Enzymes, 2nd ed. Academic Press, 2003).

Proteases are involved in a multitude of physiological reactions from simple digestion of food proteins to highly regulated cascades (e.g., the cell cycle, the blood clotting cascade, the complement system, and apoptosis pathways). It is well known to the skilled artisan that proteases can break either specific peptide bonds, depending on the amino acid sequence of a protein, or break down a polypeptide to constituent amino acids.

Among the proteases of this invention are “caspases”, a family of cysteine proteases, which cleave other proteins after an aspartic acid residue. Many of the caspases are held in an inactive form as a zymogen until they are activated by proteolytic cleavage, which converts the inactive caspase into an active conformation, allowing caspase cleavage of downstream targets. Caspases serve an essential role in apoptosis, in which a cascade of sequential caspase activation is responsible executing programmed cell death. See, e.g., Thornberry, N. L. and Lazebnik, Y., Science, 281:1312-1316 (1998); Shi, Y., Cell, 117:855-8 (2004) for reviews. As an example of this regulatory hierarchy, caspase-3 is processed into an active form through its proteolysis by caspases-8, -9, and -10. Upon activation, caspase 3 is then able to activate caspases-6 and -7 via proteolysis. Caspases-3, -6, and -7 are then able to proteolyze cellular substrates such as nuclear lamins. Caspases can also become inappropriately and acutely activated during stroke, myocardial infarction, or Parkinson's disease.

“Apoptosis” refers generally to a process of programmed cell death and involves a series of ordered molecular events leading to characteristic changes in cell morphology and death, as distinguished from general cell death or necrosis that results from exposure of cells to non-specific toxic events such as metabolic poisons or ischemia. Cells undergoing apoptosis show characteristic morphological changes such as chromatin condensation and fragmentation and breakdown of the nuclear envelope. As apoptosis proceeds, the plasma membrane is seen to form blebbings, and the apoptotic cells are either phagocytosed or else break up into smaller vesicles which are then phagocytosed. Typical assays used to detect and measure apoptosis include microscopic examination of cellular morphology, TUNEL assays for DNA fragmentation, caspase activity assays, annexin-V externalization assays, and DNA laddering assays, among others. It is well known to the skilled artisan that the process of apoptosis is controlled by a diversity of cell signals which includes extracellular signals such as hormones, growth factors, cytokines, and nitric oxide, among others. These signals may positively or negatively induce apoptosis. Other effectors of apoptosis include oncogenes (e.g., c-myc) and exposure of cancer cells to chemotherapeutic agents, among other examples.

“Inducing apoptosis” or “inducer of apoptosis” refers to an agent or process which causes a cell to undergo the program of cell death described above for apoptosis.

A “cell signal” refers to any agent which may initiate or stimulate directly or indirectly proteolysis within a cell. Examples of cell signals include agents that cause cells to undergo apoptosis such as those discussed above. In the context of this invention, a cell signal may include introduction of an activated or overexpressed oncogene, such as c-myc, or any other protein that causes a proteolytic event to occur within cells, as well as, externally applied agents (e.g., chemotherapeutic drugs, etc.).

A “peptide ester” refers generally to any peptide in which one carboxyl group of the peptide is esterified, i.e., is of the structure —CO—O—R. In embodiments of this invention, a peptide ester can serve as a substrate for subtiligase such that the peptide is added to the α-amino group of polypeptides to form the structure —CO—NH—R, thus labeling the polypeptide. In some embodiments of this invention, a peptide ester can carry a detectable label and a site for proteolysis or another form of chemical cleavage (e.g., through introduction of photolabile, acid-labile, or base-labile functional groups).

A “label” or “detectable label” or “tag” is a composition detectable by mass spectrometric, spectroscopic, photochemical, biochemical, immunochemical, or chemical means. For example, useful labels include radioactive isotopes (e.g., 3H, 35S, 32P, 51Cr, or 125I), stable isotopes (e.g., ¹³C or ¹⁵N), fluorescent dyes, electron-dense reagents, enzymes (e.g., alkaline phosphatase, horseradish peroxidase, or others commonly used in an ELISA), biotin, digoxigenin, or haptens or epitopes and proteins for which antisera or monoclonal antibodies are available. In general, a label as used in the context of the present invention is any entity that may be used to detect or isolate the product of the subtiligase ligation reaction. Thus, any entity that is capable of binding to another entity maybe used in the practice of this invention, including without limitation, epitopes for antibodies, ligands for receptors, and nucleic acids, which may interact with a second entity through means such as complementary base pair hybridization.

“Biological sample” as used herein is a sample of cells, biological tissue, or fluid that is to be tested for the occurrence of proteolysis or the presence, more generally, of polypeptides of interest in the sample. Among the cells that can be examined are cancer cells, cells stimulated to under apoptosis, and cells at different stages of development, among others. The biological tissues of this invention include any of the tissues that comprise the organs of an organism. The biological sample can be derived from any species including bacteria, yeasts, plants, invertebrates, and vertebrate organisms. The fluid of this invention can be any fluid associated with a cell or tissue. Such fluids may include the media in which cells are cultured as well as the fluid surrounding tissues and organs, as well as the fluid comprising the circulatory system of invertebrates and vertebrates (e.g., body fluids such as whole blood, serum, plasma, cerebrospinal fluid, urine, lymph fluids, and various external secretions of the respiratory, intestinal and genitourinary tracts, tears, saliva, milk, white blood cells, myelomas, and the like). An “extracellular fluid” refers generally to any fluid found exterior to cells. Such fluids may include all of the fluids described above. In certain embodiments, such fluids may further include cellular debri, for example from lysed cells, including membrane-bound and cytosolic proteins. A biological sample used in the present invention may be from a suitable organism, for example a mammal such as a mouse, rat, hamster, guinea pig, rabbit, sheep, goat, pig, monkey, human, and the like.

A “negative control” has the definition recognized by the skilled artisan and generally refers to an experiment in which the desired result is no effect. Conversely, a “positive control” is a control experiment in which the desired outcome is a well-defined or well-known effect. In the context of this invention, a negative control may be a biological sample which is not treated with an agent that provides a cell signal to stimulate proteolysis or may be a sample treated with a placebo.

“Secreted protein” refers generally to any protein that is synthesized by a cell for export to the exterior of the cell membrane, for instance, secretion to the extracellular fluid. A variety of secreted proteins are recognized by the skilled artisan including: hormones, growth factors, antibiotics, antibodies, neuropeptides, toxins, cytokines, apolipoproteins, proteases and protease inhibitors, among others.

“Disease” or “disease state” refers generally to any derangement of normal physiology. Examples of diseases relevant to the practice of this invention include, without limitation: inflammatory diseases such as rheumatoid arthritis, osteoporosis, inflammatory bowel syndrome, asthma; cardiovascular diseases such as ischemia, stroke, myocardial infarction, congestive heart failure, atherosclerosis; type I and II diabetes and diabetes related diseases such as hyperglycemia, diabetic retinopathy, peripheral neuropathy; thrombotic disorders, such as diseases affecting blood clotting or complement fixation; neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease, Huntington's disease, age-related dementia; liver diseases, such as liver infection, fibrosis, cirrhosis; kidney infection, fibrosis, and cirrhosis; muscular dystrophy; multiple sclerosis; lung diseases, such as lung fibrosis; schizophrenia and other mental disorders; and disorders of cell proliferation such as psoriasis and cancer (see below). (See, generally, Harrison's Principles of Internal Medicine, 16th edition, 2004.)

“Cancer” and “cancer cells” refers generally to human and animal cancers and carcinomas, sarcomas, adenocarcinomas, lymphomas, leukemias, etc., including solid and lymphoid cancers, kidney, breast, lung, bladder, colon, ovarian, prostate, pancreas, stomach, brain, head and neck, skin, uterine, testicular, glioma, esophagus, and liver cancer, including hepatocarcinoma, lymphoma, including B-acute lymphoblastic lymphoma, non-Hodgkin's lymphomas (e.g., Burkitt's, Small Cell, and Large Cell lymphomas) and Hodgkin's lymphoma, leukemia (including AML, ALL, and CML), multiple myeloma, mantle cell lymphoma, Waldenstrom's macrogobulinemia, and Philadelphia positive cancers, among others.

“Chemotherapeutic drugs or agents” include conventional chemotherapeutic reagents such as alkylating agents, anti-metabolites, plant alkaloids, antibiotics, and miscellaneous compounds e.g., cis-platinum, CDDP, methotrexate, vincristine, adriamycin, bleomycin, and hydroxyurea, as well as biologics, such as therapeutic antibodies. Chemotherapeutic agents can include other therapeutic approaches known in the art for treating cancer, such as radiation therapy. Chemotherapeutic drugs or agents can be used alone or in combination in the practice of the present invention. The methods of the present invention are useful in combination with adjuvant cancer therapies, including hormone therapy, chemotherapy, biologic therapy (i.e. antibody therapy), radiation therapy, immunotherapy, surgery, and the like.

By “therapeutically effective amount or dose” or “sufficient amount or dose” herein is meant a dose that produces effects for which it is administered. The exact dose will depend on the purpose of the treatment, and will be ascertainable by one skilled in the art using known techniques (see, e.g., Lieberman, Pharmaceutical Dosage Forms (vols. 1-3, 1992); Lloyd, The Art, Science and Technology of Pharmaceutical Compounding (1999); Pickar, Dosage Calculations (1999); and Remington: The Science and Practice of Pharmacy, 20th Edition, 2003, Gennaro, Ed., Lippincott, Williams & Wilkins)

“Metastasis” refers to spread of a cancer from the primary tumor or origin to other tissues and parts of the body, such as the lymph nodes.

“Providing a prognosis” refers to providing a prediction of the likelihood of metastasis, predictions of disease free and overall survival, the probable course and outcome of cancer therapy, or the likelihood of recovery from the cancer, in a subject.

“Diagnosis” refers to identification of a disease state, such as cancer, in a subject. The methods of diagnosis provided by the present invention can be combined with other methods of diagnosis well known in the art. Non-limiting examples of other methods of diagnosis include, detection of previously known disease biomarkers, including protein and nucleic acid biomarkers, radiography, co-axial tomography (CAT) scans, positron emission tomography (PET), radionuclide scanning, and the like.

The terms “cancer-associated antigen”, or “tumor-specific marker”, or “tumor marker”, or “biomarker” interchangeably refer to a molecule (typically nucleic acid, protein, proteolytic fragment, carbohydrate, or lipid) that is present in a biological sample, from a subject with cancer, expressed in a cancer cell, expressed on the surface of a cancer cell, or secreted by a cancer cell differentially in comparison to a biological sample from a subject without cancer or a non-cancer cell, and which is useful for the diagnosis of cancer, for providing a prognosis, or for preferential targeting of a pharmacological agent to the cancer cell. In the context of the present invention, a cancer-associated antigen may be a proteolytic fragment, for example one that is generated in response to an apoptotic stimulus, that is present in a biological sample, such as a blood sample, tumor biopsy, tissue, and the like, from a patient suffering from a disease, such as cancer, at an elevated level, for example, 10% greater level, 20%, 50%, 75%, 100% or greater level, than found in an biological sample from an individual not suffering from the disease. In other cases, the proteolytic fragment may be present at about 1-fold, 2, 3, 4, 5, 6, 7, 8, 9, 10, 20, 30, 40, 50, 75, 100, 250, 500, or 1000-fold greater level in a sample from a patient suffering from the disease as compared to a sample from an individual not suffering from the disease, or a control sample. In some embodiments, a biomarker of the present invention may be a proteolytic fragment that is present in a biological sample from a patient suffering from a disease, such as cancer, but not present, or present at a minimal level, in a sample from an individual not suffering from the disease. In other embodiments, a cancer-associated antigen is a molecule that is overexpressed in a biological sample from a subject with cancer or a cancer cell in comparison to a biological sample from a subject without cancer or a non-cancer cell, for instance, 1-fold over expression, 2-fold overexpression, 3-fold overexpression or more in comparison. Oftentimes, a cancer-associated antigen is a molecule that is inappropriately synthesized in a cancer cell or present in a biological sample from a subject with cancer, for instance, a molecule that contains deletions, additions or mutations in comparison to the molecule expressed in a biological sample from a subject without cancer or in a non-cancer cell.

The “proteolytic apoptotic polypeptide biomarkers” of the present invention generally relate to proteolytic polypeptides that are generated in response to an apoptotic stimulus. Typically, these fragments are formed by the cleavage of a “pro-apoptotic polypeptide” or “proteolytic apoptotic cleavage junction” by a protease involved in an apoptotic pathway. Typically, two proteolytic apoptotic polypeptide biomarkers are generated by every cleavage. For example, one proteolytic polypeptide may comprise an N-terminal sequence selected from those found in Table 1. I.e., cleavage of Serine/threonine-protein phosphatase 2A 56 kDa regulatory subunit gamma isoform, Swiss-Prot accession number Q13362, results in a proteolytic apoptotic polypeptide biomarkers comprising the sequence AANSNGPFQPVVLLHIR (SEQ ID NO:418), wherein AAN are the first three, or N-terminal, residues of the biomarker. A second proteolytic apoptotic polypeptide biomarker formed by a cleavage reaction may comprise a C-terminal sequence also found in Table 1. I.e., cleavage of Serine/threonine-protein phosphatase 2A 56 kDa regulatory subunit gamma isoform, Swiss-Prot accession number Q13362, will also result in a proteolytic apoptotic polypeptide biomarkers comprising the sequence AGSRMVVD (SEQ ID NO:419), wherein VVD are the last three, or C-terminal, residues of the biomarkers. In certain embodiments, proteolytic apoptotic polypeptide biomarkers of the invention may further comprise a fusion sequence N-terminal or C-terminal to a sequence found in Table 1, in order to facilitate purification or detection of the biomarker. Proteolytic apoptotic polypeptide biomarkers of the present invention may comprise polypeptides spanning from the cleavage site (P1 or P1′ residue) to the N- or C-terminus of the parent protein. In other embodiments, the proteolytic apoptotic polypeptide biomarkers of the invention may undergo further proteolysis prior to detection or quantitation. As such, a proteolytic apoptotic polypeptide biomarker may comprise at least about 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 35, 40, 45, 50, 55, 60, 70, 80, 90, 100, 125, 150, 175, 200, 250, 300, 400, 500, or more of the parent protein, including the identified N- or C-terminal sequence, for example those found in Table 1.

A “proteolytic apoptotic cleavage junction”, or “cleavage junction”, or “intact cleavage junction”, in the context of the present invention, refers to an amino acid sequence, or polypeptide containing said sequence, that contains a recognition motif that is cleaved by a protease under certain conditions. In one embodiment, a cleavage junction of the invention is cleaved in response to an apoptotic stimulus. In a particular embodiment, the cleavage junctions comprise a sequence selected from those found in Table 3. A cleavage junction is said to correspond to a proteolytic polypeptide or a proteolytic apoptotic polypeptide biomarker if said proteolytic polypeptide is formed or generated by the proteolysis of the cleavage junction. Thus, typically a cleavage junction of the present invention will result in the formation of two proteolytic apoptotic polypeptide biomarkers that correspond to said intact cleavage junction. In one embodiment, a cleavage junction comprising a sequence selected from those found in Table 3, with a given Swiss-Prot accession number, will correspond to two proteolytic polypeptides, one comprising an N-terminal sequence selected from those found in Table 1 and one comprising a C-terminal sequence selected from those found in Table 1, with the same Swiss-Prot accession number. For example, a cleavage junction of Table 3, Swiss-Prot accession number Q13362, would correspond to both a proteolytic polypeptide comprising a N-terminal sequence of the corresponding unmodified polypeptide sequence and a proteolytic polypeptide comprising an C-terminal sequence of the corresponding previous amino acid sequence.

In certain embodiments, the cleaved products of the present invention may be further trimmed in vivo or in vitro by exoproteases after capsase-based proteolysis. The present invention, in one embodiment, includes fragments of the biomarkers identified herein that have been further processed by such exoproteases, which may serve as biomarkers of apoptosis equivalent to their predecessor fragments. In other embodiments, the detection of either an N-terminal or C-terminal proteolytic fragment, in the absence of the other, will provide diagnostic or prognostic power for the detection of spoptosis in a biological sample.

An “apoptotic stimulus” generally refers to a signal or condition that causes or induces a cell to undergo apoptosis. Apoptotic signals may originate intracellularly, as per the action of an intrinsic inducer, or extracellularly, as in the action of an extrinsic inducer. Extracellular signals may include, without limitation, toxins, hormones, growth factors, nitric oxide, cytokines, cytotoxic dugs, and the like. Intracellular apoptotic signalling is typically initiated in response to stress. These stimuli include, without limitation, the binding of nuclear receptors by glucocorticoids, heat, radiation, nutrient deprivation, viral infection, hypoxia, and the like. In certain embodiments of the invention, apoptosis may be induced through the use of cytotoxic drugs or by environmental conditioning of the cells.

“Biological sample” includes sections of tissues such as biopsy and autopsy samples, and frozen sections taken for histologic purposes. Such samples include blood and blood fractions or products (e.g., serum, plasma, platelets, red blood cells, and the like), sputum or saliva, lymph and tongue tissue, cultured cells, e.g., primary cultures, explants, and transformed cells, stool, urine, etc. A biological sample is typically obtained from a eukaryotic organism, most preferably a mammal such as a primate e.g., chimpanzee or human; cow; dog; cat; a rodent, e.g., guinea pig, rat, Mouse; rabbit; or a bird; reptile; or fish

A “biopsy” refers to the process of removing a tissue sample for diagnostic or prognostic evaluation, and to the tissue specimen itself. Any biopsy technique known in the art can be applied to the diagnostic and prognostic methods of the present invention. The biopsy technique applied will depend on the tissue type to be evaluated (e.g., tongue, colon, prostate, kidney, bladder, lymph node, liver, bone marrow, blood cell, etc.), the size and type of the tumor (e.g., solid or suspended, blood or ascites), among other factors. Representative biopsy techniques include, but are not limited to, excisional biopsy, incisional biopsy, needle biopsy, surgical biopsy, and bone marrow biopsy. An “excisional biopsy” refers to the removal of an entire tumor mass with a small margin of normal tissue surrounding it. An “incisional biopsy” refers to the removal of a wedge of tissue that includes a cross-sectional diameter of the tumor. A diagnosis or prognosis made by endoscopy or fluoroscopy can require a “core-needle biopsy” of the tumor mass, or a “fine-needle aspiration biopsy” which generally obtains a suspension of cells from within the tumor mass. Biopsy techniques are discussed, for example, in Harrison's Principles of Internal Medicine, Kasper, et al., eds., 16th ed., 2005, Chapter 70, and throughout Part V.

The terms “identical” or percent “identity,” in the context of two or more nucleic acids or polypeptide sequences, refer to two or more sequences or subsequences that are the same or have a specified percentage of amino acid residues or nucleotides that are the same (i.e., about 60% identity, preferably 65%, 70%, 75%, 80%, 85%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99%, or higher identity over a specified region, when compared and aligned for maximum correspondence over a comparison window or designated region) as measured using a BLAST or BLAST 2.0 sequence comparison algorithms with default parameters described below, or by manual alignment and visual inspection (see, e.g., NCBI web site http://www.ncbi.nlm.nih.gov/BLAST/ or the like). Such sequences are then said to be “substantially identical.” This definition also refers to, or may be applied to, the compliment of a test sequence. The definition also includes sequences that have deletions and/or additions, as well as those that have substitutions. As described below, the preferred algorithms can account for gaps and the like. Preferably, identity exists over a region that is at least about 25 amino acids or nucleotides in length, or more preferably over a region that is 50-100 amino acids or nucleotides in length.

For sequence comparison, typically one sequence acts as a reference sequence, to which test sequences are compared. When using a sequence comparison algorithm, test and reference sequences are entered into a computer, subsequence coordinates are designated, if necessary, and sequence algorithm program parameters are designated. Preferably, default program parameters can be used, or alternative parameters can be designated. The sequence comparison algorithm then calculates the percent sequence identities for the test sequences relative to the reference sequence, based on the program parameters.

A “comparison window”, as used herein, includes reference to a segment of any one of the number of contiguous positions selected from the group consisting of from 20 to 600, usually about 50 to about 200, more usually about 100 to about 150 in which a sequence may be compared to a reference sequence of the same number of contiguous positions after the two sequences are optimally aligned. Methods of alignment of sequences for comparison are well-known in the art. Optimal alignment of sequences for comparison can be conducted, e.g., by the local homology algorithm of Smith & Waterman, Adv. Appl. Math. 2:482 (1981), by the homology alignment algorithm of Needleman & Wunsch, J. Mol. Biol. 48:443 (1970), by the search for similarity method of Pearson & Lipman, Proc. Nat'l. Acad. Sci. USA 85:2444 (1988), by computerized implementations of these algorithms (GAP, BESTFIT, FASTA, and TFASTA in the Wisconsin Genetics Software Package, Genetics Computer Group, 575 Science Dr., Madison, Wis.), or by manual alignment and visual inspection (see, e.g., Current Protocols in Molecular Biology (Ausubel et al., eds. 1987-2005, Wiley Interscience)).

A preferred example of algorithm that is suitable for determining percent sequence identity and sequence similarity are the BLAST and BLAST 2.0 algorithms, which are described in Altschul et al., Nuc. Acids Res. 25:3389-3402 (1977) and Altschul et al., J. Mol. Biol. 215:403-410 (1990), respectively. BLAST and BLAST 2.0 are used, with the parameters described herein, to determine percent sequence identity for the nucleic acids and proteins of the invention. Software for performing BLAST analyses is publicly available through the National Center for Biotechnology Information (http://www.ncbi.nlm.nih.gov/). This algorithm involves first identifying high scoring sequence pairs (HSPs) by identifying short words of length W in the query sequence, which either match or satisfy some positive-valued threshold score T when aligned with a word of the same length in a database sequence. T is referred to as the neighborhood word score threshold (Altschul et al., supra). These initial neighborhood word hits act as seeds for initiating searches to find longer HSPs containing them. The word hits are extended in both directions along each sequence for as far as the cumulative alignment score can be increased. Cumulative scores are calculated using, for nucleotide sequences, the parameters M (reward score for a pair of matching residues; always >0) and N (penalty score for mismatching residues; always <0). For amino acid sequences, a scoring matrix is used to calculate the cumulative score. Extension of the word hits in each direction are halted when: the cumulative alignment score falls off by the quantity X from its maximum achieved value; the cumulative score goes to zero or below, due to the accumulation of one or more negative-scoring residue alignments; or the end of either sequence is reached. The BLAST algorithm parameters W, T, and X determine the sensitivity and speed of the alignment. The BLASTN program (for nucleotide sequences) uses as defaults a wordlength (W) of 11, an expectation (E) of 10, M=5, N=−4 and a comparison of both strands. For amino acid sequences, the BLASTP program uses as defaults a wordlength of 3, and expectation (E) of 10, and the BLOSUM62 scoring matrix (see Henikoff & Henikoff, Proc. Natl. Acad. Sci. USA 89:10915 (1989)) alignments (B) of 50, expectation (E) of 10, M=5, N=−4, and a comparison of both strands.

“Nucleic acid” refers to deoxyribonucleotides or ribonucleotides and polymers thereof in either single- or double-stranded form, and complements thereof. The term encompasses nucleic acids containing known nucleotide analogs or modified backbone residues or linkages, which are synthetic, naturally occurring, and non-naturally occurring, which have similar binding properties as the reference nucleic acid, and which are metabolized in a manner similar to the reference nucleotides. Examples of such analogs include, without limitation, phosphorothioates, phosphoramidates, methyl phosphonates, chiral-methyl phosphonates, 2-O-methyl ribonucleotides, peptide-nucleic acids (PNAs).

Unless otherwise indicated, a particular nucleic acid sequence also implicitly encompasses conservatively modified variants thereof (e.g., degenerate codon substitutions) and complementary sequences, as well as the sequence explicitly indicated. Specifically, degenerate codon substitutions may be achieved by generating sequences in which the third position of one or more selected (or all) codons is substituted with mixed-base and/or deoxyinosine residues (Batzer et al., Nucleic Acid Res. 19:5081 (1991); Ohtsuka et al., J. Biol. Chem. 260:2605-2608 (1985); Rossolini et al., Mol. Cell. Probes 8:91-98 (1994)). The term nucleic acid is used interchangeably with gene, cDNA, mRNA, oligonucleotide, and polynucleotide.

A particular nucleic acid sequence also implicitly encompasses “splice variants” and nucleic acid sequences encoding truncated forms of cancer antigens. Similarly, a particular protein encoded by a nucleic acid implicitly encompasses any protein encoded by a splice variant or truncated form of that nucleic acid. “Splice variants,” as the name suggests, are products of alternative splicing of a gene. After transcription, an initial nucleic acid transcript may be spliced such that different (alternate) nucleic acid splice products encode different polypeptides. Mechanisms for the production of splice variants vary, but include alternate splicing of exons. Alternate polypeptides derived from the same nucleic acid by read-through transcription are also encompassed by this definition. Any products of a splicing reaction, including recombinant forms of the splice products, are included in this definition. Nucleic acids can be truncated at the 5′ end or at the 3′ end. Polypeptides can be truncated at the N-terminal end or the C-terminal end. Truncated versions of nucleic acid or polypeptide sequences can be naturally occurring or recombinantly created.

The terms “polypeptide,” “peptide” and “protein” are used interchangeably herein to refer to a polymer of amino acid residues. The terms apply to amino acid polymers in which one or more amino acid residue is an artificial chemical mimetic of a corresponding naturally occurring amino acid, as well as to naturally occurring amino acid polymers and non-naturally occurring amino acid polymer.

The term “amino acid” refers to naturally occurring and synthetic amino acids, as well as amino acid analogs and amino acid mimetics that function in a manner similar to the naturally occurring amino acids. Naturally occurring amino acids are those encoded by the genetic code, as well as those amino acids that are later modified, e.g., hydroxyproline, γ-carboxyglutamate, and O-phosphoserine. Amino acid analogs refers to compounds that have the same basic chemical structure as a naturally occurring amino acid, i.e., an α-carbon that is bound to a hydrogen, a carboxyl group, an amino group, and an R group, e.g., homoserine, norleucine, methionine sulfoxide, methionine methyl sulfonium. Such analogs have modified R groups (e.g., norleucine) or modified peptide backbones, but retain the same basic chemical structure as a naturally occurring amino acid. Amino acid mimetics refers to chemical compounds that have a structure that is different from the general chemical structure of an amino acid, but that functions in a manner similar to a naturally occurring amino acid.

Amino acids may be referred to herein by either their commonly known three letter symbols or by the one-letter symbols recommended by the IUPAC-IUB Biochemical Nomenclature Commission. Nucleotides, likewise, may be referred to by their commonly accepted single-letter codes.

“Conservatively modified variants” applies to both amino acid and nucleic acid sequences. With respect to particular nucleic acid sequences, conservatively modified variants refers to those nucleic acids which encode identical or essentially identical amino acid sequences, or where the nucleic acid does not encode an amino acid sequence, to essentially identical sequences. Because of the degeneracy of the genetic code, a large number of functionally identical nucleic acids encode any given protein. For instance, the codons GCA, GCC, GCG and GCU all encode the amino alanine. Thus, at every position where an alanine is specified by a codon, the codon can be altered to any of the corresponding codons described without altering the encoded polypeptide. Such nucleic acid variations are “silent variations,” which are one species of conservatively modified variations. Every nucleic acid sequence herein which encodes a polypeptide also describes every possible silent variation of the nucleic acid. One of skill will recognize that each codon in a nucleic acid (except AUG, which is ordinarily the only codon for methionine, and TGG, which is ordinarily the only codon for tryptophan) can be modified to yield a functionally identical molecule. Accordingly, each silent variation of a nucleic acid which encodes a polypeptide is implicit in each described sequence with respect to the expression product, but not with respect to actual probe sequences.

As to amino acid sequences, one of skill will recognize that individual substitutions, deletions or additions to a nucleic acid, peptide, polypeptide, or protein sequence which alters, adds or deletes a single amino acid or a small percentage of amino acids in the encoded sequence is a “conservatively modified variant” where the alteration results in the substitution of an amino acid with a chemically similar amino acid. Conservative substitution tables providing functionally similar amino acids are well known in the art. Such conservatively modified variants are in addition to and do not exclude polymorphic variants, interspecies homologs, and alleles of the invention.

The following eight groups each contain amino acids that are conservative substitutions for one another: 1) Alanine (A), Glycine (G); 2) Aspartic acid (D), Glutamic acid (E); 3) Asparagine (N), Glutamine (Q); 4) Arginine (R), Lysine (K); 5) Isoleucine (I), Leucine (L), Methionine (M), Valine (V); 6) Phenylalanine (F), Tyrosine (Y), Tryptophan (W); 7) Serine (S), Threonine (T); and 8) Cysteine (C), Methionine (M) (see, e.g., Creighton, Proteins (1984)).

A “label” or a “detectable moiety” is a composition detectable by spectroscopic, photochemical, biochemical, immunochemical, chemical, or other physical means. For example, useful labels include ³²P, fluorescent dyes, electron-dense reagents, enzymes (e.g., as commonly used in an ELISA), biotin, digoxigenin, or haptens and proteins which can be made detectable, e.g., by incorporating a radiolabel into the peptide or used to detect antibodies specifically reactive with the peptide.

The phrase “stringent hybridization conditions” refers to conditions under which a probe will hybridize to its target subsequence, typically in a complex mixture of nucleic acids, but to no other sequences. Stringent conditions are sequence-dependent and will be different in different circumstances. Longer sequences hybridize specifically at higher temperatures. An extensive guide to the hybridization of nucleic acids is found in Tijssen, Techniques in Biochemistry and Molecular Biology—Hybridization with Nucleic Probes, “Overview of principles of hybridization and the strategy of nucleic acid assays” (1993). Generally, stringent conditions are selected to be about 5-10° C. lower than the thermal melting point (T_(m)) for the specific sequence at a defined ionic strength pH. The T_(m) is the temperature (under defined ionic strength, pH, and nucleic concentration) at which 50% of the probes complementary to the target hybridize to the target sequence at equilibrium (as the target sequences are present in excess, at T_(m), 50% of the probes are occupied at equilibrium). Stringent conditions may also be achieved with the addition of destabilizing agents such as formamide. For selective or specific hybridization, a positive signal is at least two times background, preferably 10 times background hybridization. Exemplary stringent hybridization conditions can be as following: 50% formamide, 5×SSC, and 1% SDS, incubating at 42° C., or, 5×SSC, 1% SDS, incubating at 65° C., with wash in 0.2×SSC, and 0.1% SDS at 65° C.

Nucleic acids that do not hybridize to each other under stringent conditions are still substantially identical if the polypeptides which they encode are substantially identical. This occurs, for example, when a copy of a nucleic acid is created using the maximum codon degeneracy permitted by the genetic code. In such cases, the nucleic acids typically hybridize under moderately stringent hybridization conditions. Exemplary “moderately stringent hybridization conditions” include a hybridization in a buffer of 40% formamide, 1 M NaCl, 1% SDS at 37° C., and a wash in 1×SSC at 45° C. A positive hybridization is at least twice background. Those of ordinary skill will readily recognize that alternative hybridization and wash conditions can be utilized to provide conditions of similar stringency. Additional guidelines for determining hybridization parameters are provided in numerous reference, e.g., and Current Protocols in Molecular Biology, ed. Ausubel, et al., supra.

“Antibody” refers to a polypeptide comprising a framework region from an immunoglobulin gene or fragments thereof that specifically binds and recognizes an antigen. The recognized immunoglobulin genes include the kappa, lambda, alpha, gamma, delta, epsilon, and mu constant region genes, as well as the myriad immunoglobulin variable region genes. Light chains are classified as either kappa or lambda. Heavy chains are classified as gamma, mu, alpha, delta, or epsilon, which in turn define the immunoglobulin classes, IgG, IgM, IgA, IgD and IgE, respectively. Typically, the antigen-binding region of an antibody will be most critical in specificity and affinity of binding. Antibodies can be polyclonal or monoclonal, derived from serum, a hybridoma or recombinantly cloned, and can also be chimeric, primatized, or humanized.

An exemplary immunoglobulin (antibody) structural unit comprises a tetramer. Each tetramer is composed of two identical pairs of polypeptide chains, each pair having one “light” (about 25 kD) and one “heavy” chain (about 50-70 kD). The N-terminus of each chain defines a variable region of about 100 to 110 or more amino acids primarily responsible for antigen recognition. The terms variable light chain (V_(L)) and variable heavy chain (V_(H)) refer to these light and heavy chains respectively.

Antibodies exist, e.g., as intact immunoglobulins or as a number of well-characterized fragments produced by digestion with various peptidases. Thus, for example, pepsin digests an antibody below the disulfide linkages in the hinge region to produce F(ab)′₂, a dimer of Fab which itself is a light chain joined to V_(H)-C_(H)1 by a disulfide bond. The F(ab)′₂ may be reduced under mild conditions to break the disulfide linkage in the hinge region, thereby converting the F(ab)′₂ dimer into an Fab′ monomer. The Fab′ monomer is essentially Fab with part of the hinge region (see Fundamental Immunology (Paul ed., 3d ed. 1993). While various antibody fragments are defined in terms of the digestion of an intact antibody, one of skill will appreciate that such fragments may be synthesized de novo either chemically or by using recombinant DNA methodology. Thus, the term antibody, as used herein, also includes antibody fragments either produced by the modification of whole antibodies, or those synthesized de novo using recombinant DNA methodologies (e.g., single chain Fv) or those identified using phage display libraries (see, e.g., McCafferty et al., Nature 348:552-554 (1990))

In one embodiment, the antibody is conjugated to an “effector” moiety. The effector moiety can be any number of molecules, including labeling moieties such as radioactive labels or fluorescent labels, or can be a therapeutic moiety. In one aspect the antibody modulates the activity of a target protein or polypeptide.

The phrase “specifically (or selectively) binds” to or “specifically (or selectively) immunoreactive with” an antibody or binding reagent, when referring to a protein or peptide, refers to a binding reaction that is determinative of the presence of the protein, often in a heterogeneous population of proteins and other biologics. Similarly, an antibody or binding reagent is considered to “substantially bind” to an epitope, when the antibody or binding reagent binds to said epitope in a specific or selective fashion. Thus, under designated immunoassay conditions, the specified antibodies or binding reagents bind to a particular protein at least two times the background and more typically more than 10 to 100 times background. Specific binding to an antibody or binding reagent under such conditions requires an antibody or binding reagent that is selected for its specificity for a particular protein. For example, polyclonal antibodies can be selected to obtain only those polyclonal antibodies that are specifically immunoreactive with the selected antigen and not with other proteins. This selection may be achieved by subtracting out antibodies that cross-react with other molecules. A variety of immunoassay formats may be used to select antibodies or binding reagents specifically immunoreactive with a particular protein. For example, solid-phase ELISA immunoassays are routinely used to select antibodies specifically immunoreactive with a protein (see, e.g., Harlow & Lane, Antibodies, A Laboratory Manual (1988) for a description of immunoassay formats and conditions that can be used to determine specific immunoreactivity).

A binding reagent or antibody that “binds with a lower affinity” to a second polypeptide or to a background polypeptide will generally bind specifically to a first target polypeptide of interest with a greater affinity as compared to the binding affinity to said second polypeptide. In certain embodiments, the binding reagent or antibody will bind to the second polypeptide with at least a two fold lower affinity, or more typically at least about 10-fold, 100-fold, or 1000-fold lower affinity as compared to the binding affinity of the first or target polypeptide. In this fashion, a binding reagent or polypeptide that binds with a lower affinity to a second polypeptide can discriminate between a first target polypeptide and a second polypeptide, even when the second polypeptide is a derivative of the first polypeptide. For example, an antibody specific for a proteolytic polypeptide of the present invention may bind with a lower affinity to the corresponding proteolytic cleavage junction, or a polypeptide containing said cleavage junction, such that the target proteolytic polypeptide, or the level thereof, can be discriminated from said cleavage junction in a biological sample.

In the context of the present invention, a disease is “characterized by apoptosis” if said disease results in altered levels of apoptosis in an individual suffering from the disease. A disease may be considered to be characterized by apoptosis, for example, if levels of apoptosis are reduced or increased in an individual suffering from the disease as compared to levels in individuals not suffering from said disease. In one embodiment of the present invention, apoptosis levels may be reduced or increased by at least about 5%, or at least about 10, 15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, or 100% as compared to levels in an individual not suffering from said disease. In other embodiments, the level of apoptosis may be reduced or increased by at least about 1-fold, 2-fold, 3-fold, 4-fold, 5-fold, 6-fold, 7-fold, 8-fold, 9-fold, 10-fold or more as compared to levels in individuals not suffering from the disease. In yet other embodiments, apoptosis may be reduced or increased by at least about 1 order of magnitude, or at least about 2, 3, 4, 5, 6, 7, 8, 9, 10, or more orders of magnitude as compared to levels in an individual not suffering from the disease. Non-limiting examples of diseases that are characterized by apoptosis include, cancer, auto-imune diseases (such as Graves' disease, Lupus erythematosus, Rheumatoid arthritis, Sjögren's syndrome, multiple sclerosis, type-I diabetes mellitus, Hashimoto thyroiditis, and the like), neurodegenerative diseases (such as Parkinson's or Alzheimer's Diseases), preeclampsia, acute and chronic liver diseases, and the like.

Diagnostic Methods

The present invention provides methods of diagnosing a disease characterized by apoptosis, by examining proteolytic apoptotic biomarkers, including proteolytic polypeptides comprising an N-terminal or C-terminal sequence found in Table 1 and proteolytic apoptotic cleavage junctions comprising a sequence found in Table 3, in biological samples, including wild-type, truncated or alternatively spliced forms. Diagnosis involves determining the level of a polypeptide of the invention in a patient and then comparing the level to a baseline or range. Typically, the baseline value is representative of a polypeptide of the invention in a healthy person not suffering from the disease, as measured using biological sample such as blood, serum, saliva, urine, a tissue sample (e.g., tongue or lymph tissue), or a biopsy. Variation of the levels of a polypeptide of the invention from the baseline range (either up or down) indicates that the patient has a disease characterized by apoptosis or is at risk of developing a disease characterized by apoptosis.

Analysis of a protein can be achieved, for example, by high pressure liquid chromatography (HPLC), alone or in combination with mass spectrometry (e.g., MALDI/MS, MALDI-TOF/MS, tandem MS, etc.).

A detectable moiety can be used in the assays described herein. A wide variety of detectable moieties can be used, with the choice of label depending on the sensitivity required, ease of conjugation with the antibody, stability requirements, and available instrumentation and disposal provisions. Suitable detectable moieties include, but are not limited to, radionuclides, fluorescent dyes (e.g., fluorescein, fluorescein isothiocyanate (FITC), Oregon Green™, rhodamine, Texas red, tetrarhodimine isothiocynate (TRITC), Cy3, Cy5, etc.), fluorescent markers (e.g., green fluorescent protein (GFP), phycoerythrin, etc.), autoquenched fluorescent compounds that are activated by tumor-associated proteases, enzymes (e.g., luciferase, horseradish peroxidase, alkaline phosphatase, etc.), nanoparticles, biotin, digoxigenin, and the like.

Immunoassay techniques and protocols are generally described in Price and Newman, “Principles and Practice of Immunoassay,” 2nd Edition, Grove's Dictionaries, 1997; and Gosling, “Immunoassays: A Practical Approach,” Oxford University Press, 2000. A variety of immunoassay techniques, including competitive and non-competitive immunoassays, can be used (see, e.g., Self et al., Curr. Opin. Biotechnol., 7:60-65 (1996)). The term immunoassay encompasses techniques including, without limitation, enzyme immunoassays (EIA) such as enzyme multiplied immunoassay technique (EMIT), enzyme-linked immunosorbent assay (ELISA), IgM antibody capture ELISA (MAC ELISA), and microparticle enzyme immunoassay (MEIA); capillary electrophoresis immunoassays (CEIA); radioimmunoassays (RIA); immunoradiometric assays (IRMA); fluorescence polarization immunoassays (FPIA); and chemiluminescence assays (CL). If desired, such immunoassays can be automated. Immunoassays can also be used in conjunction with laser induced fluorescence (see, e.g., Schmalzing et al., Electrophoresis, 18:2184-93 (1997); Bao, J. Chromatogr. B. Biomed. Sci., 699:463-80 (1997)). Liposome immunoassays, such as flow-injection liposome immunoassays and liposome immunosensors, are also suitable for use in the present invention (see, e.g., Rongen et al., J. Immunol. Methods, 204:105-133 (1997)). In addition, nephelometry assays, in which the formation of protein/antibody complexes results in increased light scatter that is converted to a peak rate signal as a function of the marker concentration, are suitable for use in the methods of the present invention. Nephelometry assays are commercially available from Beckman Coulter (Brea, Calif.; Kit #449430) and can be performed using a Behring Nephelometer Analyzer (Fink et al., J. Clin. Chem. Clin. Biochem., 27:261-276 (1989)).

Specific immunological binding of the antibody or binding reagent to a protein can be detected directly or indirectly. Direct labels include fluorescent or luminescent tags, metals, dyes, radionuclides, and the like, attached to the antibody. An antibody labeled with iodine-125 (¹²⁵I) can be used. A chemiluminescence assay using a chemiluminescent antibody specific for the protein marker is suitable for sensitive, non-radioactive detection of protein levels. An antibody labeled with fluorochrome is also suitable. Examples of fluorochromes include, without limitation, DAPI, fluorescein, Hoechst 33258, R-phycocyanin, B-phycoerythrin, R-phycoerythrin, rhodamine, Texas red, and lissamine. Indirect labels include various enzymes well known in the art, such as horseradish peroxidase (HRP), alkaline phosphatase (AP), β-galactosidase, urease, and the like. A horseradish-peroxidase detection system can be used, for example, with the chromogenic substrate tetramethylbenzidine (TMB), which yields a soluble product in the presence of hydrogen peroxide that is detectable at 450 nm. An alkaline phosphatase detection system can be used with the chromogenic substrate p-nitrophenyl phosphate, for example, which yields a soluble product readily detectable at 405 nm. Similarly, a β-galactosidase detection system can be used with the chromogenic substrate o-nitrophenyl-β-D-galactopyranoside (ONPG), which yields a soluble product detectable at 410 nm. An urease detection system can be used with a substrate such as urea-bromocresol purple (Sigma Immunochemicals; St. Louis, Mo.).

A signal from the direct or indirect label can be analyzed, for example, using a spectrophotometer to detect color from a chromogenic substrate; a radiation counter to detect radiation such as a gamma counter for detection of ¹²⁵I; or a fluorometer to detect fluorescence in the presence of light of a certain wavelength. For detection of enzyme-linked antibodies, a quantitative analysis can be made using a spectrophotometer such as an EMAX Microplate Reader (Molecular Devices; Menlo Park, Calif.) in accordance with the manufacturer's instructions. If desired, the assays of the present invention can be automated or performed robotically, and the signal from multiple samples can be detected simultaneously.

The antibodies or binding reagents can be immobilized onto a variety of solid supports, such as polystyrene beads, magnetic or chromatographic matrix particles, the surface of an assay plate (e.g., microtiter wells), pieces of a solid substrate material or membrane (e.g., plastic, nylon, paper), and the like. An assay strip can be prepared by coating the antibody or a plurality of antibodies in an array on a solid support. This strip can then be dipped into the test sample and processed quickly through washes and detection steps to generate a measurable signal, such as a colored spot.

Useful physical formats comprise surfaces having a plurality of discrete, addressable locations for the detection of a plurality of different biomarkers. Such formats include protein microarrays, or “protein chips” (see, e.g., Ng et al., J. Cell Mol. Med., 6:329-340 (2002)) and certain capillary devices (see, e.g., U.S. Pat. No. 6,019,944). In these embodiments, each discrete surface location may comprise antibodies to immobilize one or more protein markers for detection at each location. Surfaces may alternatively comprise one or more discrete particles (e.g., microparticles or nanoparticles) immobilized at discrete locations of a surface, where the microparticles comprise antibodies to immobilize one or more protein markers for detection.

The analysis can be carried out in a variety of physical formats. For example, the use of microtiter plates or automation could be used to facilitate the processing of large numbers of test samples. Alternatively, single sample formats could be developed to facilitate diagnosis or prognosis in a timely fashion.

Compositions, Kits and Integrated Systems

The invention provides compositions, kits and integrated systems for practicing the assays described herein using polypeptides of the invention, antibodies or binding reagents specific for polypeptides of the invention, etc.

The invention provides assay compositions for use in solid phase assays; such compositions can include, for example, one or more antibodies or binding reagents specific for the polypeptide biomarkers of the invention immobilized on a solid support, and a labeling reagent. In each case, the assay compositions can also include additional reagents that are desirable for hybridization.

The invention also provides kits for carrying out the diagnostic or prognostic assays of the invention. The kits typically include a probe that comprises an antibody or binding reagent that specifically binds to polypeptides of the invention, and a label for detecting the presence of the probe. The kits may include several antibodies specific for the polypeptides of the invention. In one embodiment, the kits of the invention comprise at least 2, or at least about 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, 25, 30, 40, 50, 60, 70, 80, 90, 100, 125, 150, 175, 200, 250, 300 or more antibodies or binding reagents.

Optical images viewed (and, optionally, recorded) by a camera or other recording device (e.g., a photodiode and data storage device) are optionally further processed in any of the embodiments herein, e.g., by digitizing the image and storing and analyzing the image on a computer. A variety of commercially available peripheral equipment and software is available for digitizing, storing and analyzing a digitized video or digitized optical images.

One conventional system carries light from the specimen field to a cooled charge-coupled device (CCD) camera, in common use in the art. A CCD camera includes an array of picture elements (pixels). The light from the specimen is imaged on the CCD. Particular pixels corresponding to regions of the specimen are sampled to obtain light intensity readings for each position. Multiple pixels are processed in parallel to increase speed. The apparatus and methods of the invention are easily used for viewing any sample, e.g., by fluorescent or dark field microscopic techniques.

N-Terminal Labeling of Polypeptides

In general, any method of making an extract from cells or tissues from a biological sample that preserves the ability to label the N-termini of polypeptides with the reagents described below may be used in the practice of this invention. Any of a number of such methods are known in the art and are described in standard sources (see, e.g., Scopes, Protein Purification: Principles and Practice (1982)). In general, cells are disrupted to release and solubilize intracellular contents, followed by centrifugation to remove insoluble material, such as cell membranes and organelles. For tissue culture cells, a lysis buffer which may contain a detergent (e.g., Triton X-100, NP-40, among others) may be used. For adherent tissue culture cells, cell disruption can be accomplished by the process of scraping cells in the presence of the lysis buffer from culture plates using, for example, a rubber policeman. Other mechanical means can also be used to effect cell disruption. For example, cells can be lysed using a Dounce homogenizer. As recognized by the skilled artisan, additional mechanical means may be needed to prepare cell extracts from tissues, such as homogenization in a blender or sonication. (See, generally, e.g., Scopes, Protein Purification: Principles and Practice (1982).)

The labeling of polypeptides can be accomplished using any method that labels the N-terminus (i.e., α-amino group) of a polypeptide present in a complex mixture.

In one embodiment of this invention, the labeling is accomplished using the enzyme subtiligase, which is derived from the enzyme subtilisin BPN′ by converting the catalytic residue, Ser-221, to a cysteine residue, and Pro-225 to an alanine residue. The resulting double mutant protein provides the enzymatic activity of ligation of esterified peptides site-specifically onto the N termini of proteins or peptides (see, e.g., Chang, T. K. et al., Proc. Natl. Acad. Sci. U.S.A., 91, 12544-12548 (1994)). Furthermore, additional forms of subtiligase that exhibit increased stability have been generated through the introduction of additional site directed mutations into the sequence (e.g., Met-50 to Phe, Asn-76 to Asp, Asn-109 to Ser, Lys-213 to Arg, and Asn-218 to Ser). Such mutant enzymes have also been termed stabiligases and may also may be used in the practice of the present invention (see, e.g., Chang, T. K. et al., Proc. Natl. Acad. Sci. U.S.A., 91, 12544-12548 (1994)).

All of the earlier work describing the use of subtiligase and its variants disclosed the ligation of peptides and proteins in non-complex samples composed of single purified polypeptides. In this earlier work, two examples of the application of subtiligase to the ligation of proteins that were recombinantly expressed on the surface of phage particles were shown. For example, the work of Chang et al. demonstrated the ligation of phage-displayed human growth hormone variants that were randomized at the first three residues (Chang, T. K. et al., Proc. Natl. Acad. Sci. U.S.A., 91, 12544-12548 (1994)). The work of Atwell et al. demonstrated the autoligation of phage-displayed subtiligase variants that contained an N-terminal extension and were randomized at up to five different residues outside of this N-terminal extension (Atwell S. et al., Proc. Natl. Acad. Sci. U.S.A., 96, 9497-9502 (1999)). In contrast, the present invention represents a major advance, as it applies subtiligase to the ligation of polypeptides in complex mixtures of endogenous proteins as found in a variety of biological samples, not merely to simple formulations of recombinant proteins, as shown by the earlier studies. The modest amount of sample complexity in the earlier reported phage display experiments arises from minor genetic manipulations of either the human growth hormone gene or the subtiligase gene. In contrast, the complexity found in the biological samples of the present invention arises from the fact that the component polypeptides of the complex mixtures of the invention are products of a plurality of endogenous genes, which are subject to transcriptional, translational, and post-translational modulation of expression.

Furthermore, the work of Chang et al. demonstrated that subtiligase is very dependent on the primary and secondary structure of polypeptide substrates. Although subtiligase was found to exhibit broad specificity for peptide substrates, some N-terminal residues in these substrates were found to be exceedingly more preferred than others. Structural occlusion of N-termini in a protein substrate was also found to drastically affect ligation efficiency. This earlier work indicated limitations to this approach for labeling a plurality of polypeptides in complex mixtures and provided no indication of applicability to more complex samples, as the only substrates used in addition to short peptides were recombinant human growth hormone and subtiligase. In fact, those of skill in the art recognized several potential pitfalls in the implementation of subtiligase as a tool for selective labeling of polypeptide α-amines in complex mixtures. First, it was believed that only the most abundant proteins in the sample would be labeled. Second, the previous data indicated the possibility that only the most efficient substrates, based on the identity of N-terminal residues, would be labeled. Third, there existed the possibility of poor labeling of mixtures due to structural occlusion of N-termini. Fourth, there was a strong possibility that complex samples would contain inhibitors of subtiligase. Fifth, there was a prevalent concern that the peptide glycolate ester reagents would not be stable in biological samples because of the action of endogenous esterases and proteases.

However, as demonstrated below, the inventors have surprisingly found that these many pitfalls could be circumvented and have demonstrated that subtiligase may be used to efficiently label the N-termini of a plurality of polypeptides in complex mixtures, such as cell extracts and serum. For example, the inventors show that addition of a cocktail of inhibitors sufficiently blocks endogenous proteases and esterases without inhibiting subtiligase, thus, allowing for sufficient substrate to be available for ligation. Another advantage imparted by the present invention is the nature of the labeled peptide ester reagents used here. The inventors have designed versions of these reagents that are optimized for use in proteomic studies. Among other innovations, they have found that incorporation of a cleavable linker into these reagents greatly facilitates purification of labeled polypeptides from complex mixtures and subsequent analysis by tandem mass spectrometry for identification of the corresponding proteins.

Additional variants of subtiligase enzymes that have enhanced activity have also been selected through the application of phage display methods (see, e.g., Atwell, S. et al., Proc. Natl. Acad. Sci. U.S.A., 96:9497-502 (1999)). Such variants may also be used in the practice of the present invention. Furthermore, other subtilisin-like enzymes and their variants may also be engineered to be used in the practice of this invention.

Subtiligase has been used to incorporate a variety of label moieties into proteins and polypeptides, including affinity handles (e.g., biotin), immunoprobes, isotopic labels, heavy-atom derivatives, PEG moieties, and other non-natural constituents (see, e.g., Chang, T. K. et al., Proc. Natl. Acad. Sci. U.S.A., 91, 12544-12548 (1994)). The skilled artisan will recognize that this is not an exhaustive list, as for instance, any detectable label that can be incorporated into a substrate (e.g., biotin labeled peptide esters) to be used to label a free N-terminus (e.g., α-amino group of a polypeptide generated through proteolysis) may be used. In particular, any of the labels disclosed above may be used in the practice of the present invention.

The reaction by which subtiligase may be used to label a free N-terminus of a polypeptide is illustrated in FIG. 1 with a biotin labeled peptide ester as the substrate for the introduction of a biotin label onto a protein. In the first step of this reaction, a free sulhydryl group on subtiligase serves as a nucleophile to effect a nucleophilic attack on the carbonyl carbon atom of the ester moiety of the substrate peptide ester, resulting in the release of an alcohol leaving group. In a second step, the carbonyl carbon of the thioester linkage between the peptide substrate and the subtiligase enzyme is then subject to nucleophilic attack by the α-amino group of a protein or peptide. This reaction results in a covalent adduct comprising the biotin labeled peptide linked to the α-amino group on a protein or peptide via an amide bond. Accordingly, the biotin label then can serve as an affinity handle to allow the identification and isolation of polypeptides that have a free N-terminus or free α-amino group (e.g., protein fragments that have resulted from proteolysis, or native non-acetylated or otherwise N-terminally blocked proteins).

In general, any peptide ester with the following generic elements may be used in the practice of the present invention: label-linker-peptide sequence-esterified carboxyl terminus. The skilled artisan will recognize that the location of the label within this structure may be varied without affecting the operation of the present invention. The generic structure of these elements may optionally contain a protease cleavage site or other cleavable moiety to facilitate the ready removal of the label added to the α-amino group of a protein or polypeptide. Such removal also greatly facilitates downstream mass spectrometric analysis of labeled proteins or polypeptides. FIG. 6 shows a representative peptide ester that may be used in the practice of the invention. In this example, there is a biotin label at the N-terminus of the peptide ester, a site for a protease cleavage (TEV protease), and an esterified carboxyl terminus, which serves as a subtiligase cleavage site (i.e., the site for the nucleophilic attack by a free sulfhydryl group on subtiligase as described above). Among the peptide sequences that may be used in the practice of the invention include, but are not limited to: ENLYFQSY (SEQ ID NO:420), ENLYFQSK (SEQ ID NO:421), ENLYFQSA (SEQ ID NO:422), AAPY (SEQ ID NO:423), AAPK (SEQ ID NO:424), and AAPA (SEQ ID NO:425), among others. Optional protease cleavage sites that may be used in the practice of this invention include, but are not limited to: the site for TEV protease: EXXYXQ(S/G/A), where X corresponds to any amino acid; the site for rhinovirus 3C protease: E(T/V)LFQGP (SEQ ID NO:426); the site for enterokinase: DDDDK (SEQ ID NO:427); the site for Factor Xa: I(D/E)GR; the site for thrombin: LVPR (SEQ ID NO:428); the site for furin: RXXR, where X corresponds to any amino acid; and the site for Granzyme B: IEPD (SEQ ID NO:429). Some examples of the many possible moieties that may be used to esterify the carboxyl terminus of the peptide are: HO—CH2—CO—X, where X is any amino acid, in the case of glycolate esters; HO—CHCH3—CO—X, where X is any amino acid, in the case of lactate esters; HO—R, where R is an alkyl or aryl substituent; and HS—R, where R is an alkyl or aryl substituent. A number of label moieties may be used, including radioisotopes, stable isotopes, fluorophores, heavy metals, and biotin, among others.

In general, any reaction conditions that favor nucleophilic attack of a carbonyl group at an ester or thioester linkage to result in the release of the relevant leaving group (e.g., an alcohol in step one or the —SH group of subtiligase in step two) may be used in the practice of this invention for the labeling of free α-amino groups. Generally, any conditions under which ester reagents are stable to degradation and hydrolysis in complex samples; conditions under which subtiligase is stable and active; and conditions under which protein and polypeptide N-termini are free and available to react with the thioester linkage formed after the reaction of subtiligase with ester reagents are favored for the practice of this invention.

In some embodiments of this invention, the pre-existing unblocked α-amino groups of polypeptides may be blocked with a suitable N-termini blocking agent before an experimental treatment. Thus, for instance, the free, unblocked N-termini of cellular proteins may be blocked with any reagent that reacts with free α-amino groups prior to exposure of a biological sample to an agent, such as a chemotherapeutic agent, which promotes a physiological response of interest, such as apoptosis. After the experimental treatment, the newly exposed N termini which have resulted from the proteolytic events that accompany apoptosis can then be labeled using subtiligase and the ester substrates of the present invention. Examples of such blocking agents include: amine-reactive reagents such as succinimidyl esters, isothiocyanates, sulfonyl chlorides, and aldehydes, among others, provided these reagents do not contain primary or secondary amine moieties. In one embodiment, the blocking reaction can be accomplished using subtiligase and an acetylated ester.

It will be appreciated by the skilled artisan that a variety of complex samples can be labeled using the methods and compositions of the present invention. Such samples may include, without limitation, whole cells, cell extracts, media from cell cultures, serum from humans or animals, and other bodily fluids, among others. For example, the culture medium of cells stimulated with an agent that causes polypeptide secretion can be labeled using the methods of the present invention to identify polypeptides that have been secreted. As another example, proteins found on the surfaces of intact cells may be labeled to identify cell surface proteins, such as membrane proteins. The comparison of the cell surface proteins labeled in normal versus transformed cells can be used to identify, for example, tumor specific antigens. As a further example, serum or other bodily fluids from normal subjects and patients suffering from various diseases can be labeled to identify proteins that are unique to the serum of a patient population. The proteins so identified can serve as easily detected disease markers to be used in disease diagnostics. U.S. patent application Ser. No. 12/524,557 filed on Jul. 24, 2009, assigned to the same assignee as the present invention, the disclosure of which is incorporated by reference in its entirety and with particularity with reference to its teachings concerning methods for the specific N-terminal labeling and detection of peptides and proteins in complex mixtures.

EXAMPLES Example 1

This example demonstrates the identification and profiling of N-termini in normal Jurkat cells.

As a validation of a method provided by the present invention, endogenous N-termini in non-apoptotic Jurkat cells were analysed in two small-scale experiments using one-dimensional reversed-phase (1D) LC/MS/MS and two large-scale experiments using two-dimensional strong cation exchange/reversed-phase (2D) LC/MS/MS. Comparison of data obtained in both types of experiments is informative since 1D LC/MS/MS typically results in identification of abundant N-termini, whereas the increased proteomic coverage afforded by 2D LC/MS/MS results in additional identification of lower abundance N-termini. Of the combined 131 unique N-termini identified in small-scale experiments, 72% are either annotated in Swiss-Prot as native protein N-termini, or correspond to cleavages within the first 50 residues of proteins as would be expected for N-terminal signal or transit peptide processing (FIG. 2A). The remaining 28% correspond to cleavages outside the first 50 residues, arising from additional processing or constitutive protein degradation. In support of the latter notion, 51% of the combined 661 unique N-termini identified in large-scale experiments correspond to cleavages outside the first 50 residues (FIG. 2A). The increased frequency of such N-termini in large-scale experiments is consistent with the expected lower abundance for products of constitutive protein degradation.

Example 2

This example provides degradomic analysis of apoptotic Jurkat cells.

For analysis of apoptosis in Jurkat cells, several small-scale (1D) and large-scale (2D) LC/MS/MS experiments were carried out using cells treated with the topoisomerase II poison etoposide. The experiments with untreated cells described above serve as respective controls for the small- and large-scale experiments with apoptotic cells, in which a combined 244 and 733 unique N-termini, respectively, were identified. Caspases are known to exhibit strict substrate specificity for aspartate at P1, and for glycine>serine>alanine at P1′ (Schilling et al., Nat. Biotechnol. 2008; 26(6):685-94; Stennicke et al., Biochem J. 2000; 350 Pt 2:563-8). In small-scale experiments, 43% of N-termini identified in apoptotic cells were derived from P1 aspartate cleavages, in contrast to less than 1% in untreated cells (FIG. 3A). In large-scale experiments, 43% of N-termini identified in apoptotic cells were derived from P1 aspartate cleavages, in contrast to 3% in untreated cells (FIG. 3B). An increased frequency of glycine at the first position of N-termini is also observed in apoptotic cells relative to untreated cells at both experimental scales (FIGS. 3A and 3B). The N-termini uniquely identified in apoptotic Jurkat cells are thus consistent with induction of caspase-like activity.

Of the 3% P1 aspartate N-termini detected in large-scale experiments with untreated cells (FIG. 3B), 55% correspond to reported caspase substrates (Lüthi et al., Cell Death Differ. 2007; 14(4):641-50). Thus, it is likely that these originate from the small number of apoptotic cells typically present in untreated cultures. The detection of 3% P1 aspartate N-termini in large-scale experiments with untreated cells and less than 1% in small-scale experiments is consistent with the low abundance of such N-termini in cultures of normal cells. Additionally, if one considers that N-termini annotated in Swiss-Prot are representative of native N-termini in healthy cells, it is notable that <1% are derived from proteolytic processing following an aspartate residue (FIG. 4). In apoptotic samples, the increased frequency of N-termini located beyond the first 50 residues is solely attributable to P1 aspartate N-termini (FIGS. 2B and 2C). Thus, the vast majority of proteolysis we observe in apoptosis is attributable to caspases or proteases with caspase-like substrate specificity.

Among the total 1099 SY-labeled peptides identified in etoposide-treated Jurkat cells, 418 follow aspartate in corresponding protein sequences. These peptides correspond to 333 P1 aspartate N-termini and caspase-like cleavage sites. In turn, these cleavage sites map to 282 unique substrates and 10 additional others that cannot be distinguished from homologs containing the same identified cleavage site. Approximately 16 of the proteins identified as caspase substrates in these studies have been verified to be cleaved during apoptosis using immunoblotting (representative examples are indicated in FIG. 5A). The proteolysis of a representative set of substrates is also blocked by the broad-spectrum caspase inhibitor Z-VAD(OMe)-fmk, consistent with this proteolysis being caspase-dependent (FIG. 5B). Representative CID spectra for P1 aspartate peptides are included (FIGS. 8-15).

The most frequent residues at the P4, P3, P2, and P1′ positions of the caspase-like cleavage sites identified in apoptotic Jurkat cells are aspartate, glutamate, valine, and glycine, respectively (FIG. 6A). Thus, an averaged composite of these cleavage sites indicates that the most common caspase activity in apoptotic cells exhibits a specificity that is most similar to the substrate specificity of executioner caspases-3 and -7, as determined using peptide substrates (FIG. 6B) (Thornberry et al., J Biol. Chem. 1997; 272(29):17907-11). However, there are significant differences between the cellular cleavage sites and the in vitro specificity profiles. Notably, the canonical DEVD (SEQ ID NO:430) cleavage site motif is found in less than 1% of the caspase-like cleavage sites observed in apoptotic Jurkat cells, and the broader DXXD motif is still only found in 22% of the identified cleavage sites (FIG. 6D). A distinct difference in the composite cellular profile is the high frequency of serine and threonine residues at P4, P3, and P2, which is not observed in vitro for any of the caspases (FIG. 7). Interestingly, a composite of all previously reported human and human ortholog of rodent caspase cleavage sites (Lüthi et al., Cell Death Differ. 2007; 14(4):641-50.) is very similar to the Jurkat cellular profile reported here (FIG. 6C).

These observations suggest that caspase substrate specificity determined using peptide substrates has limited value as a predictor of physiological caspase cleavage sites. To investigate the predictive value of a large set of known physiological caspase cleavage sites, we constructed three profile hidden Markov models (HMMs) using the cleavage sites identified in our studies, previously reported cleavage sites, and the union of these two datasets. The accuracy of these HMMs was estimated using jackknifing and plotted in a receiver operator characteristic (ROC) plot, showing the true positive rate versus the false positive rate at different HMM score thresholds. While all three HMMs predict caspase cleavage sites relatively accurately, the HMM built from the merged substrate set performed most accurately (FIG. 6E).

Example 5

Cell culture, induction of apoptosis, and cell lysate preparation.

Jurkat clone E6-1 (ATCC) cells were grown in RPMI-1640 supplemented with 10% fetal bovine serum, sodium pyruvate, and antibiotics. Normal cells were harvested for experiments at a density of 1×10⁶ cells/ml. For apoptotic samples, cells at a density of 1×10⁶ cells/ml were treated with etoposide (50 μM) for 12 hours prior to harvesting. Harvested cells (0.1 to 1 billion) were pelleted at 2,000×g and 25° C. for 5 minutes, washed twice with phosphate buffered saline, and lysed at a typical concentration of 2×10⁸ cells/ml in 1.0% Triton X-100, 100 mM BICINE pH 8.0, 100 μM Z-VAD-FMK, 100 μM E-64, 1 mM PMSF, 1 mM AEBSF, and 5 mM EDTA. Cell lysates were incubated at room temperature for 1 hour to allow complete inhibition of endogenous protease and esterase activity, and centrifuged at 21,000×g and 4° C. for 15 minutes to pellet insoluble material. Clarified supernatant was immediately used in ligation reactions at a protein concentration of approximately 20 mg/ml, as determined by Bradford assay (Bio-Rad).

Example 6

Sample biotinylation, denaturation, reduction, alkylation, and gel filtration.

Subtiligase (1 μM), biotinylated peptide ester (1 mM), and DTT (2 mM) were added to either control or apoptotic cell lysate. Ligation reactions were typically left to proceed at room temperature for 60 minutes. Samples were then denatured by direct addition of solid guanidine hydrochloride to a final concentration of 6 M, reduced by addition of neutralized TCEP (2 mM), heated at 95° C. for 15 minutes, cooled to room temperature, and alkylated by addition of iodoacetamide (6 mM) and incubation at room temperature in the dark for 1 hour. The alkylation reaction was quenched by addition of DTT (10 mM), the sample was passed through a 0.8 μm filter, and subjected to gel filtration chromatography using a Superdex 30 16/60 column (GE Healthcare) on an ÄKTA FPLC system (GE Healthcare). The mobile phase was 100 mM BICINE pH 8.0, 200 mM NaCl, and 1 M guanidine hydrochloride. Fractions containing protein (corresponding to polypeptides greater than 5 kDa) were collected and pooled for a final volume of approximately 30 ml.

Example 7

Trypsinization and recovery of biotinylated peptides.

The gel-filtered material was supplemented with CaCl₂ (20 mM) and digested with sequencing grade modified trypsin (100 μg, Promega) by incubation at 37° C. for 12 hours.

Trypsinized samples were clarified by centrifugation, supplemented with benzamidine (500 mM), and NeutrAvidin agarose (250 μl bed volume, Pierce) was added for affinity capture of biotinylated N-terminal peptides. After 12 hours of gentle agitation, NeutrAvidin agarose resin was pelleted and washed with 100 mM BICINE pH 8.0 and AEBSF (1 mM), 100 mM BICINE pH 8.0, 5 M NaCl, and again with a few washes of 100 mM BICINE pH 8.0. More stringent washes using either 1 M or 5 M guanidine hydrochloride were used in some cases. Captured peptides were released from NeutrAvidin agarose resin by treatment with TEV protease (1 μM) in 100 mM BICINE pH 8.0 and DTT (1 mM). Recovered peptides were concentrated and desalted using ZipTip_(C18) pipette tips, or a C₁₈ Macrotrap (Michrom) trap column on a 2796 HPLC system (Waters). TEV protease was sometimes depleted from samples using an SCX Macrotrap (Michrom) trap column.

Example 9

Expression and purification of subtiligase.

The expression construct for subtiligase was prepared using the B. subtilis/E. coli shuttle vector pBS42 (ATCC) (Wells et al., Nucleic Acids Res. 1983; 11(22):7911-25). The variant of subtiligase used corresponds to subtilisin BPN′ containing point mutations S221C, P225A, M124L, and S125A for ligase activity (Abrahmsen et al., Biochemistry. 1991; 30(17):4151-9; Atwell et al., Proc Natl Acad Sci USA. 1999; 96(17):9497-502), and point mutations M50F, N76D, N109S, K213R, AND N218S for increased stability (Chang et al., Proc Natl Acad Sci USA. 1994; 91(26):12544-8). Recombinant subtiligase was prepared in B. subtilis strain 168 (ATCC). Subtiligase expression and purification was carried out essentially as described (Abrahmsen et al., Biochemistry. 1991; 30(17):4151-9). The purified enzyme was stored at −80° C. in 100 mM BICINE, pH 8.0 and 10 mM DTT or TCEP.

Example 12

Synthesis of peptide ester substrates.

Peptide glycolate ester substrates for subtiligase were prepared by solid-phase peptide synthesis using Fmoc chemistry as previously described (Braisted et al., Methods Enzymol. 1997; 289:298-313). Peptides were purified using 10×50 mm XTerra Prep MS C₁₈ ODB columns on a Parallex Flex HPLC system (Biotage). Purity and identity of peptides was verified by LC/MS analysis using a 4.6×50 mm XTerra MS C₁₈ column on a 2795 HPLC (Waters) system equipped with a ZQ quadrupole MS detector (Waters).

Example 13

Sample fractionation using strong cation exchange (SCX) chromatography.

For larger scale experiments, samples were fractionated by SCX chromatography prior to LC/MS/MS analysis using a 2.1×200 mm PolySULFOETHYL Aspartamide column (The Nest Group) at a flow rate of 0.3 ml/min on a 2796 HPLC system (Waters). Buffer A consisted of 25 mM ammonium formate pH 2.8 and 30% acetonitrile, and buffer B consisted of 500 mM ammonium formate pH 2.8 and 30% acetonitrile. Approximately 25 fractions were collected during a 40 minute gradient block from 0% to 75% buffer B. Solvent from fractions was removed using an EZ-2 Plus evaporator (GeneVac), and remaining ammonium formate salt was removed by lyophilization. Some samples were also fractionated using a phosphate buffer and KCl salt system, in which case each fraction was subjected to automated desalting using a C is Microtrap (Michrom) trap column on a 2796 HPLC system (Waters) before solvent removal.

Example 14

Nano-LC-ESI-Qq-TOF MS/MS analysis.

Desalted fractionated or unfractionated samples were separated using a 75 μm×15 cm C₁₈ column (LC Packings) at a flow rate of 350 nl/min, with a 60 minute gradient of 3 to 30% acetonitrile in 0.1% formic acid, on a 1100 series HPLC system (Agilent). The LC eluent was coupled to a microion spray source attached to a QSTAR Pulsar or QSTAR XL mass spectrometer (Applied Biosystems). Peptides were analyzed in positive ion mode. MS spectra were acquired for 1 s. For each MS spectrum, either the single most intense or the two most intense multiply charged peaks were selected for generation of subsequent CID mass spectra, depending on the analysis method used. The CID collision energy was automatically adjusted based upon peptide charge and m/z ratio. A dynamic exclusion window was applied that prevented the same m/z from being selected for 3 min after its initial acquisition. Representative CID spectra are included as FIGS. 11-18. Additional CID figures will be made available upon request.

Example 15

Interpretation of MS/MS spectra.

Data were analyzed using Analyst QS software (version 1.1), and MS/MS centroid peak lists were generated using the Mascot.dll script (version 1.6b16). Data were searched against the Swiss-Prot human database (March 2008 release) using Protein Prospector 5.0 (University of California, San Francisco). Initial peptide tolerances in MS and MS/MS modes were 200 ppm and 300 ppm, respectively. The digest protease specified was trypsin, allowing for non-specific cleavage at N-termini in searches for N-terminally labeled semitryptic peptides, and trypsin allowing for non-specific cleavage at 0 N-termini in searches for unlabeled fully tryptic peptide contaminants. Two missed cleavages were typically allowed in searches. An N-terminal SY modification was specified as a fixed modification in searches for Nterminal peptides, but not in searches for unlabeled peptides. Cysteine carbamidomethylation was specified as a fixed modification and methionine oxidation was specified as a variable modification in all searches. High scoring peptide identifications from individual LC/MS/MS runs were then used to internally recalibrate MS parent ion m/z values within each run. Recalibrated data files were then searched again with an MS peptide tolerance of 100 ppm. Peptides with scores of greater than or equal to 22 and expectation values of less than or equal to 0.05 were considered positively identified. False positive rates for peptide identifications were estimated by conducting searches using a concatenated database containing the original Swiss-Prot human database, as well as a version of each original database entry where the sequence had been randomized. The overall false positive rate for N-terminal peptides identified was found to be 2.09%, while the false positive rate for peptides following aspartic acid in corresponding protein sequences was found to be 0.71%. A representative sampling of SY-labeled peptide identifications, particularly those based on expectation values near 0.05, was also manually validated.

Example 16

Immunoblotting and DNA fragmentation analysis.

Jurkat cells at a density of 1×10⁶ cells/ml were treated with etoposide (50 μM) for 0, 2, 4, 8, 12, and 24 hours prior to harvesting. Harvested cells were pelleted at 2,000×g and 25° C. for 5 minutes, washed twice with phosphate buffered saline, and lysed at a concentration of 2×10⁷ cells/ml in 1.0% SDS, phosphate buffered saline, 100 μM Z-VAD-FMK, 100 μM E-64, 1 mM PMSF, 1 mM AEBSF, 5 mM EDTA, and 10 mM sodium butyrate. Whole cell lysates were sonicated to shear genomic DNA, normalized to a protein concentration of approximately 2 mg/ml, as determined by BCA assay (Pierce). Cell lysates for each apoptotic timepoint were then analyzed by SDS-PAGE and Western blot. Mouse monoclonal anti-caspase-3 (#9668) and rabbit polyclonal anti-HDAC3 (#2632) antibodies were purchased from Cell Signaling Technology. Mouse monoclonal anti-DFF45 (#611036) antibody was purchased from BD Transduction Laboratories. Goat polyclonal anti-N-Cor (#sc-1611) and rabbit polyclonal anti-HDAC7 (#sc-11412) antibodies were purchased from Santa Cruz Biotechnology. Rabbit polyclonal anti-TBLR1 (#A300-408A), rabbit polyclonal anti-SHARP (#A301-119A), and rabbit polyclonal anti-RBBP7 (#A300-959A) antibodies were purchased from Bethyl Laboratories. Rabbit polyclonal anti-SMRTe (#06-891) antibody was purchased from Millipore. Western blots were imaged using SuperSignal West Femto Substrate (Pierce) with a Fluor Chem SP imager (Alpha Innotech). DNA fragmentation of whole cell DNA was analyzed by agarose gel with the Apoptotic DNA Ladder Kit (Roche).

Example 17

Identification of protein N-termini in serum. Serum and plasma can be labeled by N-terminal protein biotinylation by a process similar to that described in Example 6. For example, two milliliters of human serum (NHS) supplemented with 100 mM BICINE pH 8.0, 1 mM EDTA, 1 mM PMSF, and 10% DMSO are labeled with 1 mM of biotinylated peptide ester using 1 μM subtiligase at room temperature for 15 to 120 minutes. Peptides corresponding to protein N termini of serum or plasma proteins are then recovered and identified as described in the Examples above. As a result of such an analysis, 79 nonredundant peptides can be identified in a single LC/MS/MS run, corresponding to 34 unique proteins. 68% of the peptides corresponded to annotated N termi resulting from signal cleavage or other known functional proteolytic processing. The 32% of N-terminal peptides with unknown origin indicate the potential of this technique to identify previously unknown posttranslational modifications in serum proteins. The abundances of identified proteins can span five orders of magnitude, from the processed N terminus of serum albumin (˜20 mg/ml) to insulin-like growth factor II (˜500 ng/ml). Low abundance serum proteins can be identified despite no effort being made to deplete highabundance proteins prior to analysis, illustrating the power of this labeling technique to partially neutralize dynamic range problems that confound serum proteomics. These results can be obtained without pre-fractionation of the labeled serum peptides. Significantly improved depth of coverage can be obtained with SCX fractionation.

TABLE 1 Identified caspase-derived peptides. Previous residues indicates the inferred  P8-P1 residues in the given protein substrate that directly precede the  sequence of residues corresponding to the identified peptide. Unmodified   peptide indicates the sequence of residues corresponding to the identified    peptide. Modified peptide indicates the peptide as identified, sometimes  containing chemical modifications such as oxidized methionine and  carbamidomethylated cysteine, and always containing either an N-terminal serinyl- glycyl dipeptide (SerTyr) modification or an N-terminal 2-aminobutyryl (Abu)   modification. Start residue(SR) indicates the residue number  in the full-length  protein sequence of the first residue of the unmodified peptide.  “M” indicates the number of matches. SEQ ID Swiss-Prot Swiss- unmodified NO. ID Prot acc # peptide SR M protein name 2A5G_HUMAN Q13362 15 1 Serine/threonine-protein phosphatase 2A 56 kDa regulatory subunit gamma isoform 1 3MG_HUMAN P29372 AAQAPAEQPHSSS 37 1 DNA-3-methyladenine DAAQAPCPR glycosylase 41_HUMAN P11171 551 1 Protein 4.1 41_HUMAN P11171 551 1 Protein 4.1 4EBP1_HUMAN Q13541 26 1 Eukaryotic translation initiation factor 4E-binding protein 1 4EBP2_HUMAN Q13542 27 1 Eukaryotic translation initiation factor 4E-binding protein 2 A26CA_HUMAN Q6S8J3 945 10 ANKRD26-like family C member 1A A26CB_HUMAN A5A3E0 945 ANKRD26-like family C member 1B ACTA_HUMAN P62736 247 Actin, aortic smooth muscle ACTBL_HUMAN Q562R1 246 Beta-actin-like protein 2 ACTB_HUMAN P60709 245 Actin, cytoplasmic 1 ACTC_HUMAN P68032 247 Actin, alpha cardiac muscle 1 ACTG_HUMAN P63261 245 Actin, cytoplasmic 2 ACTH_HUMAN P63267 246 Actin, gamma-enteric smooth muscle ACTK_HUMAN Q9BYX7 245 Kappa-actin ACTS_HUMAN P68133 247 Actin, alpha skeletal muscle A26CA_HUMAN Q6S8J3 945 10 ANKRD26-like family C member 1A A26CB_HUMAN A5A3E0 945 ANKRD26-like family C member 1B ACTA_HUMAN P62736 247 Actin, aortic smooth muscle ACTBL_HUMAN Q562 246 Beta-actin-like protein 2 ACTB_HUMAN P60709 245 Actin, cytoplasmic 1 ACTC_HUMAN P68032 247 Actin, alpha cardiac muscle 1 ACTG_HUMAN P63261 245 Actin, cytoplasmic 2 ACTH_HUMAN P63267 246 Actin, gamma-enteric smooth muscle ACTK_HUMAN Q9BYX7 245 Kappa-actin ACTS_HUMAN P68133 247 Actin, alpha skeletal muscle A26CA_HUMAN Q6S8J3 923 3 ANKRD26-like family C member 1A ACTB_HUMAN P60709 223 Actin, cytoplasmic 1 ACTG_HUMAN P63261 223 Actin, cytoplasmic 2 AASD1_HUMAN Q9BTE6 81 1 Alanyl-tRNA synthetase domain-containing protein 1 ABL1_HUMAN P00519 940 1 Proto-oncogene tyrosine- protein kinase ABL1 ABLM1_HUMAN O14639 568 1 Actin-binding LIM protein 1 ACAP3_HUMAN Q96P50 589 1 ArfGAP with coiled-coil, ANK repeat and PH domain- containing protein 3 ACINU_HUMAN Q9UKV3 664 1 Apoptotic chromatin condensation inducer in the nucleus ACINU_HUMAN Q9UKV3 512 1 Apoptotic chromatin condensation inducer in the nucleus ACINU_HUMAN Q9UKV3 69 1 Apoptotic chromatin condensation inducer in the nucleus ACINU_HUMAN Q9UKV3 664 1 Apoptotic chromatin condensation inducer in the nucleus ACOC_HUMAN P21399 674 1 Cytoplasmic aconitate hydratase ACSL3_HUMAN O95573 572 2 Long-chain-fatty-acid--CoA O60488 563 ligase 3 ACSL4_HUMAN Long-chain-fatty-acid--CoA ligase 4 ACTA_HUMAN P62736 54 6 Actin, aortic smooth muscle ACTB_HUMAN P60709 52 Actin, cytoplasmic 1 ACTC_HUMAN P68032 54 Actin, alpha cardiac muscle 1 ACTG_HUMAN P63261 52 Actin, cytoplasmic 2 ACTH_HUMAN P63267 53 Actin, gamma-enteric smooth muscle ACTS_HUMAN P68133 54 Actin, alpha skeletal muscle ACTA_HUMAN P62736 54 6 Actin, aortic smooth muscle ACTB_HUMAN P60709 52 Actin, cytoplasmic 1 ACTC_HUMAN P68032 54 Actin, alpha cardiac muscle 1 ACTG_HUMAN P63261 52 Actin, cytoplasmic 2 ACTH_HUMAN P63267 53 Actin, gamma-enteric smooth muscle ACTS_HUMAN P68133 54 Actin, alpha skeletal muscle ACTB_HUMAN P60709 155 2 Actin, cytoplasmic 1 ACTG_HUMAN P63261 155 Actin, cytoplasmic 2 ACTB_HUMAN P60709 158 2 Actin, cytoplasmic 1 ACTG_HUMAN P63261 158 Actin, cytoplasmic 2 ACTN1_HUMAN P12814 6 1 Alpha-actinin-1 ACTN1_HUMAN P12814 6 1 Alpha-actinin-1 ACTN1_HUMAN P12814 23 4 Alpha-actinin-1 ACTN2_HUMAN P35609 30 Alpha-actinin-2 ACTN3_HUMAN Q08043 37 Alpha-actinin-3 ACTN4_HUMAN O43707 42 Alpha-actinin-4 ADDA_HUMAN P35611 634 1 Alpha-adducin AEBP2_HUMAN Q6ZN18 234 1 Zinc finger protein AEBP2 AEDO_HUMAN Q96SZ5 35 1 2-aminoethanethiol dioxygenase AF1L2_HUMAN Q8N4X5 631 1 Actin filament-associated protein 1-like 2 AF1L2_HUMAN Q8N4X5 631 1 Actin filament-associated protein 1-like 2 AF1L2_HUMAN Q8N4X5 313 1 Actin filament-associated protein 1-like 2 AFTIN_HUMAN Q6ULP2 340 1 Aftiphilin AGGF1_HUMAN Q8N302 149 1 Angiogenic factor with G patch and FHA domains 1 AGGF1_HUMAN Q8N302 149 1 Angiogenic factor with G patch and FHA domains 1 AGGF1_HUMAN Q8N302 149 1 Angiogenic factor with G patch and FHA domains 1 AHNK_HUMAN Q09666 3719 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 1425 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 2712 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 3719 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 5581 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 576 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 3494 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 738 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 866 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 1584 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 740 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 3465 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 920 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 2883 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 4359 1 Neuroblast differentiation- associated protein AHNAK AHNK_HUMAN Q09666 1169 1 Neuroblast differentiation- associated protein AHNAK AHSA1_HUMAN O95433 255 1 Activator of 90 kDa heat shock protein ATPase homolog 1 AHSA1_HUMAN O95433 255 1 Activator of 90 kDa heat shock protein ATPase homolog 1 AHSA1_HUMAN O95433 19 1 Activator of 90 kDa heat shock protein ATPase homolog 1 AHTF1_HUMAN Q8WYP5 1368 1 AT-hook-containing transcription factor 1 AIM1_HUMAN Q9Y4K1 68 1 Absent in melanoma 1 protein AIM1_HUMAN Q9Y4K1 68 1 Absent in melanoma 1 protein AKA12_HUMAN Q02952 452 1 A-kinase anchor protein 12 AKAP2_HUMAN Q9Y2D5 473 1 A-kinase anchor protein 2 AKAP9_HUMAN Q99996 1034 1 A-kinase anchor protein 9 AKAP9_HUMAN Q99996 1034 1 A-kinase anchor protein 9 AKNA_HUMAN Q7Z591 800 1 AT-hook-containing transcription factor AKP13_HUMAN Q12802 545 1 A-kinase anchor protein 13 AKP13_HUMAN Q12802 545 1 A-kinase anchor protein 13 AKP13_HUMAN Q12802 830 1 A-kinase anchor protein 13 AKP13_HUMAN Q12802 906 1 A-kinase anchor protein 13 AKP13_HUMAN Q12802 1056 1 A-kinase anchor protein 13 AKP13_HUMAN Q12802 1540 1 A-kinase anchor protein 13 AKP8L_HUMAN Q9ULX6 109 1 A-kinase anchor protein 8- like ALMS1_HUMAN Q8TCU4 428 1 Alstrom syndrome protein 1 ALMS1_HUMAN Q8TCU4 780 1 Alstrom syndrome protein 1 ALMS1_HUMAN Q8TCU4 591 1 Alstrom syndrome protein 1 2 ALO17_HUMAN Q9HCF4 AVAEPANAVK 274 1 Protein ALO17 3 ALO17_HUMAN Q9HCF4 AVAEPANAVKGA 274 1 Protein ALO17 GK 4 ALO17_HUMAN Q9HCF4 AVAEPANAVKGA 274 1 Protein ALO17 GKEMK AMPD3_HUMAN Q01432 37 1 AMP deaminase 3 AMPM1_HUMAN P53582 13 1 Methionine aminopeptidase 1 ANKH1_HUMAN Q8IWZ3 1049 1 Ankyrin repeat and KH domain-containing protein 1 ANKH1_HUMAN Q8IWZ3 5 1 Ankyrin repeat and KH domain-containing protein 1 ANKS6_HUMAN Q68DC2 276 1 Ankyrin repeat and SAM domain-containing protein 6 ANS1A_HUMAN Q92625 530 1 Ankyrin repeat and SAM domain-containing protein 1A ANXA2_HUMAN P07355 17 2 Annexin A2 AXA2L_HUMAN A6NMY6 17 Putative annexin A2-like protein AP1G1_HUMAN O43747 690 1 AP-1 complex subunit gamma-1 AP1G2_HUMAN O75843 632 1 AP-1 complex subunit gamma-like 2 AP2A2_HUMAN O94973 691 1 AP-2 complex subunit alpha-2 AP3B2_HUMAN Q13367 844 1 AP-3 complex subunit beta-2 AP3B2_HUMAN Q13367 844 1 AP-3 complex subunit beta-2 APBB2_HUMAN Q92870 280 1 Amyloid beta A4 precursor protein-binding family B member 2 APC_HUMAN P25054 1499 1 Adenomatous polyposis coli protein APMAP_HUMAN Q9HDC9 23 1 Adipocyte plasma membrane-associated protein APTX_HUMAN Q7Z2E3 142 1 Aprataxin AR13B_HUMAN Q3SXY8 242 1 ADP-ribosylation factor-like protein 13B ARBK1_HUMAN P25098 528 1 Beta-adrenergic receptor kinase 1 ARBK1_HUMAN P25098 482 2 Beta-adrenergic receptor kinase 1 ARBK2_HUMAN P35626 482 Beta-adrenergic receptor kinase 2 ARBK1_HUMAN P25098 482 2 Beta-adrenergic receptor kinase 1 ARBK2_HUMAN P35626 482 Beta-adrenergic receptor kinase 2 ARHG1_HUMAN Q92888 293 1 Rho guanine nucleotide exchange factor 1 ARHG2_HUMAN Q92974 627 1 Rho guanine nucleotide exchange factor 2 ARHGA_HUMAN O15013 1247 1 Rho guanine nucleotide exchange factor 10 ARI1A_HUMAN O14497 607 1 AT-rich interactive domain- containing protein 1A ARI1A_HUMAN O14497 607 1 AT-rich interactive domain- containing protein 1A ARI1A_HUMAN O14497 76 1 AT-rich interactive domain- containing protein 1A ARI4A_HUMAN P29374 1031 1 AT-rich interactive domain- containing protein 4A ARI4B_HUMAN Q4LE39 1073 1 AT-rich interactive domain- containing protein 4B ARID2_HUMAN Q68CP9 626 1 AT-rich interactive domain- containing protein 2 ARID2_HUMAN Q68CP9 630 1 AT-rich interactive domain- containing protein 2 ARM10_HUMAN Q8N2F6 87 1 Armadillo repeat-containing protein 10 ARMC6_HUMAN Q6NXE6 83 1 Armadillo repeat-containing protein 6 ARMC6_HUMAN Q6NXE6 83 1 Armadillo repeat-containing protein 6 ARNT_HUMAN P27540 152 1 Aryl hydrocarbon receptor nuclear translocator ARP21_HUMAN Q9UBL0 495 1 cAMP-regulated phosphoprotein 21 ARP2_HUMAN P61160 162 1 Actin-related protein 2 ARP3_HUMAN P61158 60 1 Actin-related protein 3 ARPC5_HUMAN O15511 30 1 Actin-related protein 2/3 complex subunit 5 ARPC5_HUMAN O15511 33 1 Actin-related protein 2/3 complex subunit 5 ARS2_HUMAN Q9BXP5 162 1 Arsenite-resistance protein 2 ASB13_HUMAN Q8WXK3 52 1 Ankyrin repeat and SOCS box protein 13 ASCC1_HUMAN Q8N9N2 35 1 Activating signal cointegrator 1 complex subunit 1 ASCC2_HUMAN Q9H1I8 622 1 Activating signal cointegrator 1 complex subunit 2 ASHWN_HUMAN Q9BVC5 106 1 Ashwin ASPP2_HUMAN Q13625 528 1 Apoptosis-stimulating of p53 protein 2 ATAD5_HUMAN Q96QE3 285 1 ATPase family AAA domain-containing protein 5 ATD2B_HUMAN Q9ULI0 78 1 ATPase family AAA domain-containing protein 2B ATF1_HUMAN P18846 47 1 Cyclic AMP-dependent transcription factor ATF-1 5 ATF4_HUMAN P18848 GLVSPSNNSKEDA 66 1 Cyclic AMP-dependent FSGTDWMLEK transcription factor ATF-4 ATF7_HUMAN P17544 44 1 Cyclic AMP-dependent transcription factor ATF-7 ATF7_HUMAN P17544 44 1 Cyclic AMP-dependent transcription factor ATF-7 ATG3_HUMAN Q9NT62 105 1 Autophagy-related protein 3 ATG3_HUMAN Q9NT62 105 1 Autophagy-related protein 3 ATG4B_HUMAN Q9Y4P1 3 1 Cysteine protease ATG4B ATRX_HUMAN P46100 920 1 Transcriptional regulator ATRX ATX1L_HUMAN P0C7T5 309 1 Ataxin-1-like ATX2L_HUMAN Q8WWM7 585 1 Ataxin-2-like protein ATX2L_HUMAN Q8WWM7 585 1 Ataxin-2-like protein ATX2_HUMAN Q99700 843 1 Ataxin-2 6 ATX3_HUMAN P54252 GSGMLDEDEEDL 218 1 Ataxin-3 QR AZI1_HUMAN Q9UPN4 549 1 5-azacytidine-induced protein 1 BA2D1_HUMAN Q9Y520 889 1 BAT2 domain-containing protein 1 BA2D1_HUMAN Q9Y520 2190 1 BAT2 domain-containing protein 1 BAP1_HUMAN Q92560 312 1 Ubiquitin carboxyl-terminal hydrolase BAP1 BAP31_HUMAN P51572 165 1 B-cell receptor-associated protein 31 BAP31_HUMAN P51572 165 1 B-cell receptor-associated protein 31 BASP_HUMAN P80723 166 1 Brain acid soluble protein 1 BASP_HUMAN P80723 172 1 Brain acid soluble protein 1 BAT3_HUMAN P46379 1002 1 Large proline-rich protein BAT3 BAT3_HUMAN P46379 1002 1 Large proline-rich protein BAT3 BAZ1A_HUMAN Q9NRL2 500 1 Bromodomain adjacent to zinc finger domain protein 1A 7 BCAP_HUMAN Q6ZUJ8 SVTDTEPEDEK 149 1 Phosphoinositide 3-kinase adapter protein 1 8 BCAP_HUMAN Q6ZUJ8 SVTDTEPEDEKVV 149 1 Phosphoinositide 3-kinase SYSK adapter protein 1 BCLF1_HUMAN Q9NYF8 325 1 Bcl-2-associated transcription factor 1 BCLF1_HUMAN Q9NYF8 383 1 Bcl-2-associated transcription factor 1 BCR_HUMAN P11274 244 1 Breakpoint cluster region protein BDP1_HUMAN A6H8Y1 526 1 Transcription factor TFIIIB component B″ homolog BID_HUMAN P55957 76 1 BH3-interacting domain death agonist BIG3_HUMAN Q5TH69 293 1 Brefeldin A-inhibited guanine nucleotide-exchange protein 3 BIN1_HUMAN O00499 302 1 Myc box-dependent- interacting protein 1 BIRC6_HUMAN Q9NR09 462 1 Baculoviral IAP repeat- containing protein 6 BL1S3_HUMAN Q6QNY0 65 1 Biogenesis of lysosome- related organelles complex 1 subunit 3 9 BLNK_HUMAN Q8WV28 YVVPVEDNDENY 178 1 B-cell linker protein IHPTESSSPPPEK BNIP2_HUMAN Q12982 84 1 BCL2/adenovirus E1B 19 kDa protein-interacting protein 2 BPTF_HUMAN Q12830 1626 1 Nucleosome-remodeling factor subunit BPTF BRD1_HUMAN O95696 922 1 Bromodomain-containing protein 1 BRD4_HUMAN O60885 338 1 Bromodomain-containing protein 4 BRD8_HUMAN Q9H0E9 561 1 Bromodomain-containing protein 8 BTB14_HUMAN Q96RE7 175 1 BTB/POZ domain- containing protein 14B BUB1_HUMAN O43683 396 1 Mitotic checkpoint serine/threonine-protein kinase BUB1 BUB1_HUMAN O43683 396 1 Mitotic checkpoint serine/threonine-protein kinase BUB1 BUD13_HUMAN Q9BRD0 274 1 BUD13 homolog C170L_HUMAN Q96L14 51 1 Cep170-like protein C1QBP_HUMAN Q07021 186 1 Complement component 1 Q sub component-binding protein, mitochondrial C2C2L_HUMAN O14523 443 1 C2 domain-containing protein 2-like C2D1A_HUMAN Q6P1N0 31 1 Coiled-coil and C2 domain- containing protein 1A C2D1A_HUMAN Q6P1N0 31 1 Coiled-coil and C2 domain- containing protein 1A C2D1B_HUMAN Q5T0F9 461 1 Coiled-coil and C2 domain- containing protein 1B CA059_HUMAN Q5T8I9 14 1 UPF0486 protein C1orf59 CA059_HUMAN Q5T8I9 14 1 UPF0486 protein C1orf59 CA103_HUMAN Q5T3J3 516 1 Uncharacterized protein C1orf103 CA103_HUMAN Q5T3J3 516 1 Uncharacterized protein C1orf103 CA163_HUMAN Q96BR5 121 1 Hcp beta-lactamase-like protein C1orf163 CA165_HUMAN Q7L4P6 104 1 Coiled-coil domain- containing protein C1orf165 CA170_HUMAN Q5SV97 43 1 Uncharacterized protein C1orf170 CA175_HUMAN Q68CQ1 412 1 Uncharacterized protein C1orf175 CA1L1_HUMAN Q08AD1 422 1 Calmodulin-regulated spectrin-associated protein 1- like protein 1 CABL2_HUMAN Q9BTV7 59 1 CDK5 and ABL1 enzyme substrate 2 CACO1_HUMAN Q9P1Z2 135 1 Calcium-binding and coiled- coil domain-containing protein 1 CADH2_HUMAN P19022 800 1 Cadherin-2 CADH2_HUMAN P19022 800 1 Cadherin-2 CAF1A_HUMAN Q13111 615 1 Chromatin assembly factor 1 subunit A CAF1A_HUMAN Q13111 111 1 Chromatin assembly factor 1 subunit A CAF1A_HUMAN Q13111 111 1 Chromatin assembly factor 1 subunit A CALR_HUMAN P27797 259 1 Calreticulin CALR_HUMAN P27797 329 1 Calreticulin 10 CALR_HUMAN P27797 MHGDSEYNIMFG 122 1 Calreticulin PDICGPGTK CAMKV_HUMAN Q8NCB2 408 1 CaM kinase-like vesicle- associated protein CAMLG_HUMAN P49069 10 1 Calcium signal-modulating cyclophilin ligand CAMLG_HUMAN P49069 10 1 Calcium signal-modulating cyclophilin ligand CAMLG_HUMAN P49069 116 1 Calcium signal-modulating cyclophilin ligand CAMP1_HUMAN Q5T5Y3 752 1 Calmodulin-regulated spectrin-associated protein 1 CAMP1_HUMAN Q5T5Y3 1255 1 Calmodulin-regulated spectrin-associated protein 1 CAMP1_HUMAN Q5T5Y3 1255 1 Calmodulin-regulated spectrin-associated protein 1 CAPR1_HUMAN Q14444 95 1 Caprin-1 CAPZB_HUMAN P47756 150 1 F-actin-capping protein subunit beta CASC3_HUMAN O15234 390 1 Protein CASC3 CASC5_HUMAN Q8NG31 1195 1 Protein CASC5 CASP3_HUMAN P42574 29 1 Caspase-3 CASP3_HUMAN P42574 176 1 Caspase-3 CASP3_HUMAN P42574 176 1 Caspase-3 CASP7_HUMAN P55210 199 1 Caspase-7 CASP_HUMAN Q13948 388 2 Protein CASP CUX1_HUMAN P39880 377 Homeobox protein cut-like 1 CATB_HUMAN P07858 78 1 Cathepsin B CB044_HUMAN Q9H6R7 509 1 WD repeat-containing protein C2orf44 CBL_HUMAN P22681 807 1 E3 ubiquitin-protein ligase CBL CBWD1_HUMAN Q9BRT8 185 6 COBW domain-containing protein 1 CBWD2_HUMAN Q8IUF1 185 COBW domain-containing protein 2 CBWD3_HUMAN Q5JTY5 185 COBW domain-containing protein 3 CBWD5_HUMAN Q5RIA9 185 COBW domain-containing protein 5 CBWD6_HUMAN Q4V339 185 COBW domain-containing protein 6 CBWD7_HUMAN A6NM15 37 COBW domain-containing protein 7 CC104_HUMAN Q96G28 142 1 Coiled-coil domain- containing protein 104 11 CC104_HUMAN Q96G28 GSDVVSDLEHEE 142 1 Coiled-coil domain- MK containing protein 104 CC104_HUMAN Q96G28 145 1 Coiled-coil domain- containing protein 104 CC104_HUMAN Q96G28 145 1 Coiled-coil domain- containing protein 104 CC124_HUMAN Q96CT7 150 1 Coiled-coil domain- containing protein 124 CC131_HUMAN O60293 336 1 Coiled-coil domain- containing protein 131 12 CC50A_HUMAN Q9NV96 GGPPCAPGGTAK 13 1 Cell cycle control protein 50A CCD43_HUMAN Q96MW1 17 1 Coiled-coil domain- containing protein 43 CCD53_HUMAN Q9Y3C0 5 1 Coiled-coil domain- containing protein 53 CCD91_HUMAN Q7Z6B0 100 1 Coiled-coil domain- containing protein 91 CCD97_HUMAN Q96F63 53 1 Coiled-coil domain- containing protein 97 CCDC9_HUMAN Q9Y3X0 300 1 Coiled-coil domain- containing protein 9 CCDC9_HUMAN Q9Y3X0 300 1 Coiled-coil domain- containing protein 9 CCNT2_HUMAN O60583 455 1 Cyclin-T2 CCNT2_HUMAN O60583 455 1 Cyclin-T2 CD2L1_HUMAN P21127 406 1 PITSLRE serine/threonine- protein kinase CDC2L1 CD2L1_HUMAN P21127 406 1 PITSLRE serine/threonine- protein kinase CDC2L1 CD2L5_HUMAN Q14004 1354 1 Cell division cycle 2-like protein kinase 5 CDC27_HUMAN P30260 237 1 Cell division cycle protein 27 homolog CDC27_HUMAN P30260 244 1 Cell division cycle protein 27 homolog CDC5L_HUMAN Q99459 392 1 Cell division cycle 5-like protein CDCA7_HUMAN Q9BWT1 40 1 Cell division cycle- associated protein 7 CDV3_HUMAN Q9UKY7 123 1 Protein CDV3 homolog 13 CDYL1_HUMAN Q9Y232 GFQSESPEKLDPV 211 1 Chromodomain Y-like EQGQEDTVAPEV protein AAEKPVGALLGP GAER CE022_HUMAN Q49AR2 197 1 UPF0489 protein C5orf22 CE152_HUMAN O94986 63 1 Centrosomal protein of 152 kDa CE170_HUMAN Q5SW79 1325 1 Centrosomal protein of 170 kDa CE170_HUMAN Q5SW79 1325 1 Centrosomal protein of 170 kDa CE170_HUMAN Q5SW79 937 1 Centrosomal protein of 170 kDa CEBPZ_HUMAN Q03701 918 1 CCAAT/enhancer-binding protein zeta CEBPZ_HUMAN Q03701 775 1 CCAAT/enhancer-binding protein zeta CEBPZ_HUMAN Q03701 956 1 CCAAT/enhancer-binding protein zeta CH041_HUMAN Q6NXR4 5 1 Uncharacterized protein C8orf41 CH082_HUMAN Q6P1X6 26 1 UPF0598 protein C8orf82 CH60_HUMAN P10809 505 1 60 kDa heat shock protein, mitochondrial CH60_HUMAN P10809 112 1 60 kDa heat shock protein, mitochondrial CH60_HUMAN P10809 453 1 60 kDa heat shock protein, mitochondrial CH60_HUMAN P10809 453 1 60 kDa heat shock protein, mitochondrial CHD3_HUMAN Q12873 373 3 Chromodomain-helicase- DNA-binding protein 3 CHD4_HUMAN Q14839 364 Chromodomain-helicase- DNA-binding protein 4 CHD5_HUMAN Q8TDI0 337 Chromodomain-helicase- DNA-binding protein 5 14 CHD4_HUMAN Q14839 GGGDNKEGEDSS 1234 1 Chromodomain-helicase- VIHYDDK DNA-binding protein 4 15 CHD4_HUMAN Q14839 GGGDNKEGEDSS 1234 1 Chromodomain-helicase- VIHYDDKAIER DNA-binding protein 4 16 CHD7_HUMAN Q9P2D1 GFYMEDGDPSVA 2286 1 Chromodomain-helicase- QLLHER DNA-binding protein 7 17 CHM4B_HUMAN Q9H444 GTLSTIEFQR 84 3 Charged multivesicular body protein 4b 17 CHM4C_HUMAN Q96CF2 GTLSTIEFQR 84 Charged multivesicular body protein 4c CI080_HUMAN Q9NRY2 58 1 Uncharacterized protein C9orf80 CJ018_HUMAN Q5VWN6 1208 1 Uncharacterized protein C10orf18 CJ047_HUMAN Q86WR7 110 1 Uncharacterized protein C10orf47 CK059_HUMAN Q6IAA8 73 1 UPF0404 protein C11orf59 CK059_HUMAN Q6IAA8 73 1 UPF0404 protein C11orf59 CL035_HUMAN Q9HCM1 360 1 Uncharacterized protein C12orf35 CL035_HUMAN Q9HCM1 502 1 Uncharacterized protein C12orf35 CL043_HUMAN Q96C57 73 1 Uncharacterized protein C12orf43 CL043_HUMAN Q96C57 205 1 Uncharacterized protein C12orf43 CL043_HUMAN Q96C57 205 1 Uncharacterized protein C12orf43 CL043_HUMAN Q96C57 205 1 Uncharacterized protein C12orf43 CLAP1_HUMAN Q7Z460 1219 1 CLIP-associating protein 1 CLAP1_HUMAN Q7Z460 1219 1 CLIP-associating protein 1 CLCA_HUMAN P09496 77 1 Clathrin light chain A CLCA_HUMAN P09496 77 1 Clathrin light chain A CLCA_HUMAN P09496 93 1 Clathrin light chain A CLIC1_HUMAN O00299 142 1 Chloride intracellular channel protein 1 CLIP1_HUMAN P30622 398 1 CAP-Gly domain-containing linker protein 1 CLSPN_HUMAN Q9HAW4 564 1 Claspin CND2_HUMAN Q15003 200 1 Condensin complex subunit 2 18 CND2_HUMAN Q15003 GSLGDDFDANDE 367 1 Condensin complex subunit 2 PDHTAVGDHEEFR CND2_HUMAN Q15003 381 1 Condensin complex subunit 2 CND2_HUMAN Q15003 171 1 Condensin complex subunit 2 CND2_HUMAN Q15003 200 1 Condensin complex subunit 2 CNDH2_HUMAN Q6IBW4 460 1 Condensin-2 complex subunit H2 CO6A3_HUMAN P12111 2616 1 Collagen alpha-3(VI) chain COBL1_HUMAN Q53SF7 984 1 Cordon-bleu protein-like 1 19 COPA_HUMAN P53621 GFVEATEGLGDD 857 1 Coatomer subunit alpha ALGK 20 COPA_HUMAN P53621 LFGTTDAVVK 189 1 Coatomer subunit alpha COPB2_HUMAN P35606 855 1 Coatomer subunit beta′ COR1A_HUMAN P31146 395 2 Coronin-1A CP088_HUMAN Q1ED39 183 1 Protein C16orf88 CP110_HUMAN Q7Z7A1 1396 1 Centriolin CP110_HUMAN Q7Z7A1 802 1 Centriolin CPIN1_HUMAN Q6FI81 215 1 Anamorsin CPNE1_HUMAN Q99829 465 1 Copine-1 CPNE3_HUMAN O75131 429 1 Copine-3 CPSF6_HUMAN Q16630 55 1 Cleavage and polyadenylation specificity factor subunit 6 CPSF7_HUMAN Q8N684 325 1 Cleavage and polyadenylation specificity factor subunit 7 CPSF7_HUMAN Q8N684 30 1 Cleavage and polyadenylation specificity factor subunit 7 CPSF7_HUMAN Q8N684 34 1 Cleavage and polyadenylation specificity factor subunit 7 CPZIP_HUMAN Q6JBY9 273 1 Capz-interacting protein CQ056_HUMAN Q96N21 381 1 Uncharacterized protein C17orf56 CQ085_HUMAN Q53F19 158 1 Uncharacterized protein C17orf85 CQ085_HUMAN Q53F19 232 1 Uncharacterized protein C17orf85 CR025_HUMAN Q96B23 45 1 Uncharacterized protein C18orf25 CR025_HUMAN Q96B23 45 1 Uncharacterized protein C18orf25 CR025_HUMAN Q96B23 45 1 Uncharacterized protein C18orf25 21 CR025_HUMAN Q96B23 GVADSTVISSMPC 45 1 Uncharacterized protein LLMELR C18orf25 22 CR025_HUMAN Q96B23 GVADSTVISSMPC 45 1 Uncharacterized protein LLMELRR C18orf25 CREB1_HUMAN P16220 230 1 cAMP response element- binding protein CREB1_HUMAN P16220 117 1 cAMP response element- binding protein CREB1_HUMAN P16220 117 1 cAMP response element- binding protein CROCC_HUMAN Q5TZA2 579 1 Rootletin CS043_HUMAN Q9BQ61 63 1 Uncharacterized protein C19orf43 CS044_HUMAN Q9H6X5 369 1 Uncharacterized protein C19orf44 CSN1_HUMAN Q13098 95 1 COP9 signalosome complex subunit 1 CSRN2_HUMAN Q9H175 40 1 Cysteine/serine-rich nuclear protein 2 CSTF3_HUMAN Q12996 577 1 Cleavage stimulation factor 77 kDa subunit CTBL1_HUMAN Q8WYA6 67 1 Beta-catenin-like protein 1 CTCF_HUMAN P49711 47 1 Transcriptional repressor CTCF CTCF_HUMAN P49711 47 1 Transcriptional repressor CTCF CTCF_HUMAN P49711 47 1 Transcriptional repressor CTCF CTNB1_HUMAN P35222 116 1 Catenin beta-1 CTND1_HUMAN O60716 162 1 Catenin delta-1 CTR9_HUMAN Q6PD62 1121 1 RNA polymerase-associated protein CTR9 homolog CUL4B_HUMAN Q13620 26 1 Cullin-4B CUTC_HUMAN Q9NTM9 34 1 Copper homeostasis protein cutC homolog CUX1_HUMAN P39880 1340 1 Homeobox protein cut-like 1 23 CYB5B_HUMAN O43169 GKGQEVETSVTY 11 1 Cytochrome b5 type B YR DBPA_HUMAN P16989 270 1 DNA-binding protein A DBPA_HUMAN P16989 162 1 DNA-binding protein A DBPA_HUMAN P16989 145 1 DNA-binding protein A DBPA_HUMAN P16989 138 3 DNA-binding protein A YBOX1_HUMAN P67809 106 Nuclease-sensitive element- binding protein 1 YBOX2_HUMAN Q9Y2T7 141 Y-box-binding protein 2 DCNL2_HUMAN Q6PH85 43 1 DCN1-like protein 2 DCTN1_HUMAN Q14203 303 1 Dynactin subunit 1 DD19A_HUMAN Q9NUU7 5 1 ATP-dependent RNA helicase DDX19A DDX1_HUMAN Q92499 440 1 ATP-dependent RNA helicase DDX1 24 DDX24_HUMAN Q9GZR7 ALPDDTVIESEAL 297 1 ATP-dependent RNA PSDIAAEAR helicase DDX24 DDX46_HUMAN Q7L014 872 1 Probable ATP-dependent RNA helicase DDX46 DDX46_HUMAN Q7L014 923 1 Probable ATP-dependent RNA helicase DDX46 DDX46_HUMAN Q7L014 872 1 Probable ATP-dependent RNA helicase DDX46 DDX46_HUMAN Q7L014 872 1 Probable ATP-dependent RNA helicase DDX46 25 DDX59_HUMAN Q5T1V6 AVATEAATIDR 44 1 Probable ATP-dependent RNA helicase DDX59 DESM_HUMAN P17661 265 1 Desmin DESM_HUMAN P17661 265 1 Desmin DFFA_HUMAN O00273 7 1 DNA fragmentation factor subunit alpha DFFA_HUMAN O00273 222 1 DNA fragmentation factor subunit alpha DFFA_HUMAN O00273 222 1 DNA fragmentation factor subunit alpha 26 DGCR8_HUMAN Q8WYQ5 ALLEEGLCAPK 249 1 Protein DGCR8 DGCR8_HUMAN Q8WYQ5 397 1 Protein DGCR8 27 DGCR8_HUMAN Q8WYQ5 SMGADPGPPDEK 397 1 Protein DGCR8 DPLGAEAAPGAL GQVK 28 DGCR8_HUMAN Q8WYQ5 SMGADPGPPDEK 397 1 Protein DGCR8 DPLGAEAAPGAL GQVKAK DGKH_HUMAN Q86XP1 583 1 Diacylglycerol kinase eta 29 DGKH_HUMAN Q86XP1 SVPGPAVAASKE 699 1 Diacylglycerol kinase eta NLPVLNTR DGLB_HUMAN Q8NCG7 549 1 Sn1-specific diacylglycerol lipase beta DHAK_HUMAN Q3LXA3 363 1 Dihydroxyacetone kinase DHAK_HUMAN Q3LXA3 363 1 Dihydroxyacetone kinase DHX30_HUMAN Q7L2E3 207 1 Putative ATP-dependent RNA helicase DHX30 DHX37_HUMAN Q8IY37 574 1 Probable ATP-dependent RNA helicase DHX37 DHX9_HUMAN Q08211 168 1 ATP-dependent RNA helicase A DHX9_HUMAN Q08211 97 1 ATP-dependent RNA helicase A DHX9_HUMAN Q08211 97 1 ATP-dependent RNA helicase A DIAP1_HUMAN O60610 649 1 Protein diaphanous homolog 1 DIDO1_HUMAN Q9BTC0 1251 1 Death-inducer obliterator 1 DIDO1_HUMAN Q9BTC0 1519 1 Death-inducer obliterator 1 DIDO1_HUMAN Q9BTC0 1353 1 Death-inducer obliterator 1 DIDO1_HUMAN Q9BTC0 1353 1 Death-inducer obliterator 1 DIDO1_HUMAN Q9BTC0 988 1 Death-inducer obliterator 1 DLG1_HUMAN Q12959 413 1 Disks large homolog 1 DNJC7_HUMAN Q99615 9 1 DnaJ homolog subfamily C member 7 DNJC7_HUMAN Q99615 9 1 DnaJ homolog subfamily C member 7 30 DNJC7_HUMAN Q99615 VVMAATEPELLD 9 1 DnaJ homolog subfamily C DQEAK member 7 31 DNJC7_HUMAN Q99615 VVMAATEPELLD 9 1 DnaJ homolog subfamily C DQEAKR member 7 DNM1L_HUMAN O00429 580 1 Dynamin-1-like protein DNM1L_HUMAN O00429 504 1 Dynamin-1-like protein DNM1L_HUMAN O00429 504 1 Dynamin-1-like protein DNM1L_HUMAN O00429 504 1 Dynamin-1-like protein DNM1L_HUMAN O00429 504 1 Dynamin-1-like protein 32 DNM3A_HUMAN Q9Y6K1 MWVEPEAAAYAP 439 1 DNA (cytosine-5)- PPPAKKPR methyltransferase 3A DOC10_HUMAN Q96BY6 328 1 Dedicator of cytokinesis protein 10 33 DOHH_HUMAN Q9BU89 AIGQTLVDPK 9 1 Deoxyhypusine hydroxylase 34 DOHH_HUMAN Q9BU89 AIGQTLVDPKQPL 9 1 Deoxyhypusine hydroxylase QAR DOT1L_HUMAN Q8TEK3 1334 1 Histone-lysine N- methyltransferase, H3 lysine- 79 specific 35 DP13A_HUMAN Q9UKG1 SLVAPDTPIQFDII 445 1 DCC-interacting protein 13- SPVCEDQPGQAK alpha 36 DPOD1_HUMAN P28340 HYVGPAQPVPGG 103 1 DNA polymerase delta PPPSR catalytic subunit 37 DPOD1_HUMAN P28340 HYVGPAQPVPGG 103 1 DNA polymerase delta PPPSRGSVPVLR catalytic subunit 38 DPOLA_HUMAN P09884 GIGYVEDGR 84 1 DNA polymerase alpha catalytic subunit DPP9_HUMAN Q86TI2 14 1 Dipeptidyl peptidase 9 DPYL4_HUMAN O14531 457 1 Dihydropyrimidinase-related protein 4 DREB_HUMAN Q16643 341 1 Drebrin DREB_HUMAN Q16643 478 1 Drebrin DSRAD_HUMAN P55265 215 1 Double-stranded RNA- specific adenosine deaminase DTL_HUMAN Q9NZJ0 579 1 Denticleless protein homolog DTL_HUMAN Q9NZJ0 579 1 Denticleless protein homolog DTX3L_HUMAN Q8TDB6 218 1 Protein deltex-3-like DYHC1_HUMAN Q14204 4368 1 Cytoplasmic dynein 1 heavy chain 1 DYHC1_HUMAN Q14204 4221 1 Cytoplasmic dynein 1 heavy chain 1 E400N_HUMAN Q6ZTU2 184 2 EP400 N-terminal-like protein EP400_HUMAN Q96L91 195 E1A-binding protein p400 E41L2_HUMAN O43491 913 1 Band 4.1-like protein 2 EAP1_HUMAN Q9H1B7 133 1 Enhanced at puberty protein 1 EBP2_HUMAN Q99848 212 1 Probable rRNA-processing protein EBP2 ECE1_HUMAN P42892 34 1 Endothelin-converting enzyme 1 39 ECT2_HUMAN Q9H8V3 GCPANLLSSHR 629 1 Protein ECT2 EDC4_HUMAN Q6P2E9 797 1 Enhancer of mRNA- decapping protein 4 EDC4_HUMAN Q6P2E9 663 1 Enhancer of mRNA- decapping protein 4 EDC4_HUMAN Q6P2E9 663 1 Enhancer of mRNA- decapping protein 4 EDC4_HUMAN Q6P2E9 491 1 Enhancer of mRNA- decapping protein 4 EDC4_HUMAN Q6P2E9 486 1 Enhancer of mRNA- decapping protein 4 40 EDC4_HUMAN Q6P2E9 SLGADGTHGAGA 486 1 Enhancer of mRNA- MESAAGVLIK decapping protein 4 EDC4_HUMAN Q6P2E9 58 1 Enhancer of mRNA- decapping protein 4 41 EDRF1_HUMAN Q3B7T1 SVGNDVDVVSDS 116 1 Erythroid differentiation- ENIK related factor 1 42 EDRF1_HUMAN Q3B7T1 SVGNDVDVVSDS 116 1 Erythroid differentiation- ENIKK related factor 1 43 EEA1_HUMAN Q15075 SSAELQSLEQQLE 133 1 Early endosome antigen 1 EAQTENFNIK 44 EEA1_HUMAN Q15075 GLVTDSSAELQSL 128 1 Early endosome antigen 1 EQQLEEAQTENF NIK EF1A1_HUMAN P68104 399 2 Elongation factor 1-alpha 1 EF1A3_HUMAN Q5VTE0 399 Putative elongation factor 1- alpha-like 3 EF1A1_HUMAN P68104 404 2 Elongation factor 1-alpha 1 EF1A3_HUMAN Q5VTE0 404 Putative elongation factor 1- alpha-like 3 EF1A1_HUMAN P68104 404 2 Elongation factor 1-alpha 1 EF1A3_HUMAN Q5VTE0 404 Putative elongation factor 1- alpha-like 3 EF1A1_HUMAN P68104 200 2 Elongation factor 1-alpha 1 EF1A3_HUMAN Q5VTE0 200 Putative elongation factor 1- alpha-like 3 EF1A1_HUMAN P68104 234 2 Elongation factor 1-alpha 1 EF1A3_HUMAN Q5VTE0 234 Putative elongation factor 1- alpha-like 3 EF1A1_HUMAN P68104 404 2 Elongation factor 1-alpha 1 EF1A3_HUMAN Q5VTE0 404 Putative elongation factor 1- alpha-like 3 45 EF1B_HUMAN P24534 LFGSDDEEESEEA 103 1 Elongation factor 1-beta KR 46 EF1B_HUMAN P24534 LFGSDDEEESEEAK 103 1 Elongation factor 1-beta EF1D_HUMAN P29692 159 1 Elongation factor 1-delta EF1D_HUMAN P29692 159 1 Elongation factor 1-delta EF2_HUMAN P13639 612 1 Elongation factor 2 47 EH1L1_HUMAN Q8N3D4 SQQPPGGSSPSEE 1330 1 EH domain-binding protein PPPSPGEEAGLQR 1-like protein 1 EHBP1_HUMAN Q8NDI1 275 1 EH domain-binding protein 1 EHD1_HUMAN Q9H4M9 416 1 EH domain-containing protein 1 EHMT1_HUMAN Q9H9B1 330 1 Histone-lysine N- methyltransferase, H3 lysine- 9 specific 5 EHMT1_HUMAN Q9H9B1 482 1 Histone-lysine N- methyltransferase, H3 lysine- 9 specific 5 EHMT2_HUMAN Q96KQ7 454 1 Histone-lysine N- methyltransferase, H3 lysine- 9 specific 3 EIF3B_HUMAN P55884 4 1 Eukaryotic translation initiation factor 3 subunit B EIF3B_HUMAN P55884 185 1 Eukaryotic translation initiation factor 3 subunit B EIF3G_HUMAN O75821 8 1 Eukaryotic translation initiation factor 3 subunit G 48 EIF3J_HUMAN O75822 NWDDDDDEKKE 51 1 Eukaryotic translation EAEVKPEVK initiation factor 3 subunit J ELF1_HUMAN P32519 146 1 ETS-related transcription factor Elf-1 49 ELF1_HUMAN P32519 GIPEVMETQQVQ 146 1 ETS-related transcription EK factor Elf-1 ENOA_HUMAN P06733 204 1 Alpha-enolase ENPL_HUMAN P14625 60 1 Endoplasmin ENPL_HUMAN P14625 29 1 Endoplasmin ENPL_HUMAN P14625 29 1 Endoplasmin EP15R_HUMAN Q9UBC2 570 1 Epidermal growth factor receptor substrate 15-like 1 EP15_HUMAN P42566 619 1 Epidermal growth factor receptor substrate 15 EPC1_HUMAN Q9H2F5 28 1 Enhancer of polycomb homolog 1 EPN1_HUMAN Q9Y6I3 461 1 Epsin-1 EPN2_HUMAN O95208 340 1 Epsin-2 ERC6L_HUMAN Q2NKX8 802 1 DNA excision repair protein ERCC-6-like ERCC6_HUMAN Q03468 53 1 DNA excision repair protein ERCC-6 ERF3A_HUMAN P15170 40 1 Eukaryotic peptide chain release factor GTP-binding subunit ERF3A ERF3A_HUMAN P15170 40 1 Eukaryotic peptide chain release factor GTP-binding subunit ERF3A ERF3A_HUMAN P15170 40 1 Eukaryotic peptide chain release factor GTP-binding subunit ERF3A 50 ERF3A_HUMAN P15170 GRPPEESAHEMM 40 1 Eukaryotic peptide chain EEEEEIPKPK release factor GTP-binding subunit ERF3A 51 ERF_HUMAN P50548 GTSELEEPLGEDPR 192 1 ETS domain-containing transcription factor ERF ERIC1_HUMAN Q86X53 277 1 Glutamate-rich protein 1 ESYT2_HUMAN A0FGR8 760 1 Extended synaptotagmin-2 ETUD1_HUMAN Q7Z2Z2 933 1 Elongation factor Tu GTP- binding domain-containing protein 1 ETUD1_HUMAN Q7Z2Z2 933 1 Elongation factor Tu GTP- binding domain-containing protein 1 EXDL2_HUMAN Q9NVH0 199 1 Exonuclease 3′-5′ domain- like-containing protein 2 52 F101B_HUMAN Q8N5W9 AAAATPAAPSPAS 62 1 Protein FAM101B LPLAPGCALR F107B_HUMAN Q9H098 6 1 Protein FAM107B 53 F117B_HUMAN Q6P1L5 GHRAPPPLVQR 375 1 Protein FAM117B 54 F125A_HUMAN Q96EY5 AASQPSKGGLLER 173 1 Protein FAM125A F169A_HUMAN Q9Y6X4 447 1 UPF0611 protein FAM169A FA13A_HUMAN O94988 595 1 Protein FAM13A1 FA13A_HUMAN O94988 595 1 Protein FAM13A1 FA21A_HUMAN Q641Q2 1135 4 Protein FAM21A FA21B_HUMAN Q5SNT6 1047 Protein FAM21B FA21C_HUMAN Q9Y4E1 1114 Protein FAM21C FA21D_HUMAN Q5SRD0 102 Protein FAM21D FA29A_HUMAN Q7Z4H7 569 1 Protein FAM29A 55 FA44A_HUMAN Q8NFC6 GLMATTASGDIT 2045 1 Protein FAM44A NQNSLAGGKNQGK FA44A_HUMAN Q8NFC6 1484 1 Protein FAM44A FA44A_HUMAN Q8NFC6 2045 1 Protein FAM44A FA44A_HUMAN Q8NFC6 2045 1 Protein FAM44A FA44A_HUMAN Q8NFC6 2045 1 Protein FAM44A FA44A_HUMAN Q8NFC6 1709 1 Protein FAM44A FAS_HUMAN P49327 1166 1 Fatty acid synthase FETUA_HUMAN P02765 134 1 Alpha-2-HS-glycoprotein FIP1_HUMAN Q6UN15 159 1 Pre-mRNA 3′-end-processing factor FIP1 FKB15_HUMAN Q5T1M5 307 1 FK506-binding protein 15 FKB15_HUMAN Q5T1M5 307 1 FK506-binding protein 15 FLI1_HUMAN Q01543 21 1 Friend leukemia integration 1 transcription factor 56 FLNA_HUMAN P21333 GSPVPSSPFQVPV 1337 1 Filamin-A TEGCDPSR 57 FLNA_HUMAN P21333 GSPVPSSPFQVPV 1337 1 Filamin-A TEGCDPSRVR FLNA_HUMAN P21333 2537 1 Filamin-A FLNA_HUMAN P21333 26 1 Filamin-A FLNA_HUMAN P21333 1505 1 Filamin-A 58 FLNA_HUMAN P21333 GVPVPGSPFPLEA 1049 1 Filamin-A VAPTKPSK 59 FLNA_HUMAN P21333 GVPVPGSPFPLEA 1049 1 Filamin-A VAPTKPSKVK 60 FLNA_HUMAN P21333 GVPVPGSPFPLEA 1049 1 Filamin-A VAPTKPSKVKAF GPGLQGGSAGSP AR FLNA_HUMAN P21333 35 3 Filamin-A FLNB_HUMAN O75369 8 Filamin-B FLNC_HUMAN Q14315 28 Filamin-C FLNB_HUMAN O75369 479 1 Filamin-B FLNB_HUMAN O75369 1022 1 Filamin-B FLNB_HUMAN O75369 1477 1 Filamin-B FLNB_HUMAN O75369 1477 1 Filamin-B FNBP1_HUMAN Q96RU3 520 1 Formin-binding protein 1 FNBP1_HUMAN Q96RU3 520 1 Formin-binding protein 1 FNBP4_HUMAN Q8N3X1 154 1 Formin-binding protein 4 FNBP4_HUMAN Q8N3X1 426 1 Formin-binding protein 4 FNBP4_HUMAN Q8N3X1 778 1 Formin-binding protein 4 FOXJ2_HUMAN Q9P0K8 213 1 Forkhead box protein J2 61 FOXK1_HUMAN P85037 SAVAGAAPALVA 81 1 Forkhead box protein K1 AAAASVR FOXO3_HUMAN O43524 55 1 Forkhead box protein O3 62 FOXP4_HUMAN Q8IVH2 GLVHPPTSAAAPV 407 1 Forkhead box protein P4 TPLRPPGLGSASL HGGGPAR FRAP_HUMAN P42345 2460 1 FKBP12-rapamycin complex-associated protein FRAP_HUMAN P42345 2460 1 FKBP12-rapamycin complex-associated protein FRYL_HUMAN O94915 1513 1 Protein furry homolog-like FUBP1_HUMAN Q96AE4 182 1 Far upstream element- binding protein 1 FUBP1_HUMAN Q96AE4 84 1 Far upstream element- binding protein 1 FUBP1_HUMAN Q96AE4 140 2 Far upstream element- binding protein 1 FUBP2_HUMAN Q92945 184 Far upstream element- binding protein 2 63 FUBP2_HUMAN Q92945 SISSQLGPIHPPPR 129 1 Far upstream element- binding protein 2 64 FUBP3_HUMAN Q96I24 SNSTIQEILIPASK 160 1 Far upstream element- binding protein 3 FUBP3_HUMAN Q96I24 35 1 Far upstream element- binding protein 3 65 FUS_HUMAN P35637 GKEFSGNPIKVSF 356 1 RNA-binding protein FUS ATR 66 FUS_HUMAN P35637 GKEFSGNPIK 356 1 RNA-binding protein FUS FXR2_HUMAN P51116 562 1 Fragile X mental retardation syndrome-related protein 2 FYB_HUMAN O15117 656 1 FYN-binding protein 67 FYB_HUMAN O15117 GAGNLDEEQDSE 447 1 FYN-binding protein GETYEDIEASK 68 FYB_HUMAN O15117 GAGNLDEEQDSE 447 1 FYN-binding protein GETYEDIEASKER FYN_HUMAN P06241 20 1 Proto-oncogene tyrosine- protein kinase Fyn FYTD1_HUMAN Q96QD9 327 2 Forty-two-three domain- containing protein 1 THOC4_HUMAN Q86V81 THO complex subunit 4 FYV1_HUMAN Q9Y2I7 1608 1 FYVE finger-containing phosphoinositide kinase FYV1_HUMAN Q9Y2I7 1608 1 FYVE finger-containing phosphoinositide kinase FYV1_HUMAN Q9Y2I7 990 1 FYVE finger-containing phosphoinositide kinase G3P_HUMAN P04406 90 1 Glyceraldehyde-3-phosphate dehydrogenase GABP1_HUMAN Q06547 304 1 GA-binding protein subunit beta-1 GABP1_HUMAN Q06547 304 1 GA-binding protein subunit beta-1 GABP2_HUMAN Q8TAK5 305 1 GA-binding protein subunit beta-2 GALT_HUMAN P07902 19 1 Galactose-1-phosphate uridylyltransferase 69 GAPD1_HUMAN Q14C86 SASQAAHPQDSA 1103 1 GTPase-activating protein FSYR and VPS9 domain-containing protein 1 70 GAPD1_HUMAN Q14C86 SASQAAHPQDSA 1103 1 GTPase-activating protein FSYRDAK and VPS9 domain-containing protein 1 GATA2_HUMAN P23769 47 1 Endothelial transcription factor GATA-2 71 GBF1_HUMAN Q92538 SASVHDMDYVNPR 369 1 Golgi-specific brefeldin A- resistance guanine nucleotide exchange factor 1 GBF1_HUMAN Q92538 SASVHDMDYVNPR 369 1 Golgi-specific brefeldin A- resistance guanine nucleotide exchange factor 1 GCFC_HUMAN Q9Y5B6 222 1 GC-rich sequence DNA- binding factor homolog GCP2_HUMAN Q9BSJ2 773 1 Gamma-tubulin complex component 2 GCP60_HUMAN Q9H3P7 16 1 Golgi resident protein GCP60 72 GCP60_HUMAN Q9H3P7 SSEKELEPEAAEE 344 1 Golgi resident protein ALENGPK GCP60 GDIR2_HUMAN P52566 20 1 Rho GDP-dissociation inhibitor 2 GDIR2_HUMAN P52566 20 1 Rho GDP-dissociation inhibitor 2 GDIR2_HUMAN P52566 56 1 Rho GDP-dissociation inhibitor 2 GELS_HUMAN P06396 640 1 Gelsolin 73 GELS_HUMAN P06396 GLGLSYLSSHIAN 404 1 Gelsolin VER 74 GEMI5_HUMAN Q8TEQ6 TASTEETDPETSQ 1320 1 Gem-associated protein 5 PEPNRPSELDLR GEMI8_HUMAN Q9NWZ8 170 1 Gem-associated protein 8 GEN_HUMAN Q17RS7 624 1 Flap endonuclease GEN homolog 1 GFPT1_HUMAN Q06210 261 1 Glucosamine--fructose-6- phosphate aminotransferase [isomerizing] 1 GGA3_HUMAN Q9NZ52 334 1 ADP-ribosylation factor- binding protein GGA3 GGA3_HUMAN Q9NZ52 518 1 ADP-ribosylation factor- binding protein GGA3 GIT1_HUMAN Q9Y2X7 633 1 ARF GTPase-activating protein GIT1 GIT1_HUMAN Q9Y2X7 419 1 ARF GTPase-activating protein GIT1 GIT1_HUMAN Q9Y2X7 419 1 ARF GTPase-activating protein GIT1 GIT1_HUMAN Q9Y2X7 633 1 ARF GTPase-activating protein GIT1 GIT2_HUMAN Q14161 626 1 ARF GTPase-activating protein GIT2 GLGB_HUMAN Q04446 308 1 1,4-alpha-glucan-branching enzyme GLRX3_HUMAN O76003 102 1 Glutaredoxin-3 GLRX3_HUMAN O76003 102 1 Glutaredoxin-3 GLU2B_HUMAN P14314 102 1 Glucosidase 2 subunit beta GLU2B_HUMAN P14314 102 1 Glucosidase 2 subunit beta GLU2B_HUMAN P14314 227 1 Glucosidase 2 subunit beta GLU2B_HUMAN P14314 95 1 Glucosidase 2 subunit beta 75 GMIP_HUMAN Q9P107 GGGEVSSQGPEDS 843 1 GEM-interacting protein LLGTQSR GMIP_HUMAN Q9P107 425 1 GEM-interacting protein GMIP_HUMAN Q9P107 473 1 GEM-interacting protein 76 GNL1_HUMAN P36915 SAMEPTGPTQER 344 1 Guanine nucleotide-binding protein-like 1 77 GNL1_HUMAN P36915 SAMEPTGPTQER 344 1 Guanine nucleotide-binding YKDGVVTIGCVG protein-like 1 FPNVGK GNL1_HUMAN P36915 53 1 Guanine nucleotide-binding protein-like 1 GNL1_HUMAN P36915 344 1 Guanine nucleotide-binding protein-like 1 GNL1_HUMAN P36915 50 1 Guanine nucleotide-binding protein-like 1 GOGB1_HUMAN Q14789 1246 1 Golgin subfamily B member 1 GOGB1_HUMAN Q14789 1802 1 Golgin subfamily B member 1 78 GOGB1_HUMAN Q14789 SLSMSTRPTCSES 1802 1 Golgin subfamily B member 1 VPSAK GON4L_HUMAN Q3T8J9 482 1 GON-4-like protein 79 GPKOW_HUMAN Q92917 GAGPSPEEKDFLK 38 1 G patch domain and KOW motifs-containing protein 80 GPKOW_HUMAN Q92917 GAGPSPEEK 38 1 G patch domain and KOW motifs-containing protein 81 GPKOW_HUMAN Q92917 GAGPSPEEKDFLK 38 1 G patch domain and KOW TVEGR motifs-containing protein GPKOW_HUMAN Q92917 99 1 G patch domain and KOW motifs-containing protein GPKOW_HUMAN Q92917 99 1 G patch domain and KOW motifs-containing protein GPN1_HUMAN Q9HCN4 312 1 GPN-loop GTPase 1 GPTC8_HUMAN Q9UKJ3 883 1 G patch domain-containing protein 8 GRDN_HUMAN Q3V6T2 220 1 Girdin GRDN_HUMAN Q3V6T2 485 1 Girdin GRIN1_HUMAN Q7Z2K8 307 1 G protein-regulated inducer of neurite outgrowth 1 82 GSDMD_HUMAN P57764 GQIQGSVELAAPG 88 1 Gasdermin-D QAK 83 GSDMD_HUMAN P57764 GVPAEGAFTEDF 276 1 Gasdermin-D QGLR GSTP1_HUMAN P09211 92 1 Glutathione S-transferase P GSTP1_HUMAN P09211 92 1 Glutathione S-transferase P GTF2I_HUMAN P78347 106 1 General transcription factor II-I GTF2I_HUMAN P78347 106 1 General transcription factor II-I H2AY_HUMAN O75367 173 1 Core histone macro-H2A.1 H4_HUMAN P62805 70 1 Histone H4 H4_HUMAN P62805 70 1 Histone H4 H4_HUMAN P62805 70 1 Histone H4 84 H4_HUMAN P62805 NIQGITKPAIR 26 1 Histone H4 HAP28_HUMAN Q13442 25 1 28 kDa heat- and acid-stable phosphoprotein HAP28_HUMAN Q13442 25 1 28 kDa heat- and acid-stable phosphoprotein HBS1L_HUMAN Q9Y450 30 1 HBS1-like protein 85 HCLS1_HUMAN P14317 FVNDISEKEQR 27 1 Hematopoietic lineage cell- specific protein 86 HCLS1_HUMAN P14317 FVNDISEK 27 1 Hematopoietic lineage cell- specific protein HDAC4_HUMAN P56524 9 1 Histone deacetylase 4 HDAC4_HUMAN P56524 290 1 Histone deacetylase 4 HDAC6_HUMAN Q9UBN7 1089 1 Histone deacetylase 6 HDAC6_HUMAN Q9UBN7 1089 1 Histone deacetylase 6 87 HDAC7_HUMAN Q8WUI4 GGGPGQVVDDGL 413 1 Histone deacetylase 7 EHR HDC_HUMAN Q9UBI9 324 1 Headcase protein homolog HDGR2_HUMAN Q7Z4V5 31 1 Hepatoma-derived growth factor-related protein 2 HDGR2_HUMAN Q7Z4V5 242 1 Hepatoma-derived growth factor-related protein 2 HDGR2_HUMAN Q7Z4V5 242 1 Hepatoma-derived growth factor-related protein 2 HDGR2_HUMAN Q7Z4V5 31 1 Hepatoma-derived growth factor-related protein 2 HECD1_HUMAN Q9ULT8 1493 1 E3 ubiquitin-protein ligase HECTD1 88 HELLS_HUMAN Q9NRZ9 TAVITPAMLEEEE 23 1 Lymphoid-specific helicase QLEAAGLER HG2A_HUMAN P04233 23 1 HLA class II histocompatibility antigen gamma chain 89 HG2A_HUMAN P04233 LISNNEQLPMLGR 23 1 HLA class II histocompatibility antigen gamma chain HIRP3_HUMAN Q9BW71 111 1 HIRA-interacting protein 3 90 HJURP_HUMAN Q8NCD3 GSVQAAAWGPEL 92 1 Holliday junction recognition PSHR protein 91 HMHA1_HUMAN Q92619 GGAGASAFEQAD 663 1 Minor histocompatibility LNGMTPELPVAV protein HA-1 PSGPFRHEGLSK 92 HMHA1_HUMAN Q92619 AGCLPAEEVDVL 263 1 Minor histocompatibility LQR protein HA-1 93 HMHA1_HUMAN Q92619 AVFPGPSLEPPAG 40 1 Minor histocompatibility SSGVK protein HA-1 HMOX2_HUMAN P30519 252 1 Heme oxygenase 2 HMOX2_HUMAN P30519 252 1 Heme oxygenase 2 HMOX2_HUMAN P30519 252 1 Heme oxygenase 2 HNRH1_HUMAN P31943 341 1 Heterogeneous nuclear ribonucleoprotein H HNRH1_HUMAN P31943 95 2 Heterogeneous nuclear ribonucleoprotein H HNRH2_HUMAN P55795 95 Heterogeneous nuclear ribonucleoprotein H2 HNRH1_HUMAN P31943 95 2 Heterogeneous nuclear ribonucleoprotein H HNRH2_HUMAN P55795 95 Heterogeneous nuclear ribonucleoprotein H2 HNRH1_HUMAN P31943 252 2 Heterogeneous nuclear ribonucleoprotein H HNRH2_HUMAN P55795 252 Heterogeneous nuclear ribonucleoprotein H2 HNRH2_HUMAN P55795 341 1 Heterogeneous nuclear ribonucleoprotein H2 94 HNRH3_HUMAN P31942 GGYGGFDDYGGY 145 1 Heterogeneous nuclear NNYGYGNDGFDDR ribonucleoprotein H3 HNRL1_HUMAN Q9BUJ2 97 1 Heterogeneous nuclear ribonucleoprotein U-like protein 1 95 HNRL1_HUMAN Q9BUJ2 GHYAMDNITR 97 1 Heterogeneous nuclear ribonucleoprotein U-like protein 1 96 HNRL2_HUMAN Q1KMD3 ASEKPAEATAGS 127 1 Heterogeneous nuclear GGVNGGEEQGLGK ribonucleoprotein U-like protein 2 97 HNRL2_HUMAN Q1KMD3 ASEKPAEATAGS 127 1 Heterogeneous nuclear GGVNGGEEQGLG ribonucleoprotein U-like protein 2 HNRLL_HUMAN Q8WVV9 290 1 Heterogeneous nuclear ribonucleoprotein L-like HNRPD_HUMAN Q14103 70 1 Heterogeneous nuclear ribonucleoprotein D0 HNRPF_HUMAN P52597 252 1 Heterogeneous nuclear ribonucleoprotein F HNRPG_HUMAN P38159 284 1 Heterogeneous nuclear ribonucleoprotein G HNRPG_HUMAN P38159 234 1 Heterogeneous nuclear ribonucleoprotein G 98 HNRPK_HUMAN P61978 AVECLNYQHYK 129 1 Heterogeneous nuclear ribonucleoprotein K 99 HNRPK_HUMAN P61978 AVECLNYQHYKG 129 1 Heterogeneous nuclear SDFDCELR ribonucleoprotein K 100 HNRPK_HUMAN P61978 SAIDTWSPSEWQ 347 1 Heterogeneous nuclear MAYEPQGGSGYD ribonucleoprotein K YSYAGGR 101 HNRPK_HUMAN P61978 YSYAGGR 371 2 Heterogeneous nuclear ribonucleoprotein K 102 HNRPL_HUMAN P14866 YTNPNLSGQGDP 285 1 Heterogeneous nuclear GSNPNKR ribonucleoprotein L HNRPQ_HUMAN O60506 469 1 Heterogeneous nuclear ribonucleoprotein Q HOOK1_HUMAN Q9UJC3 234 1 Protein Hook homolog 1 HOOK1_HUMAN Q9UJC3 234 1 Protein Hook homolog 1 103 HOOK2_HUMAN Q96ED9 SLSPETYGNFDSQ 161 1 Protein Hook homolog 2 SR HPS4_HUMANM Q9NQG7 496 1 Hermansky-Pudlak syndrome 4 protein HRX_HUMAN Q03164 2719 1 Histone-lysine N- methyltransferase HRX HRX_HUMAN Q03164 2719 1 Histone-lysine N- methyltransferase HRX HRX_HUMAN Q03164 2385 1 Histone-lysine N- methyltransferase HRX HS105_HUMAN Q92598 548 1 Heat shock protein 105 kDa HS105_HUMAN Q92598 548 1 Heat shock protein 105 kDa HS105_HUMAN Q92598 548 1 Heat shock protein 105 kDa HS71L_HUMAN P34931 228 6 Heat shock 70 kDa protein 1L HSP71_HUMAN P08107 226 Heat shock 70 kDa protein 1 HSP72_HUMAN P54652 229 Heat shock-related 70 kDa protein 2 HSP76_HUMAN P17066 228 Heat shock 70 kDa protein 6 HSP77_HUMAN P48741 228 Putative heat shock 70 kDa protein 7 HSP7C_HUMAN P11142 226 Heat shock cognate 71 kDa protein HSP74_HUMAN P34932 728 1 Heat shock 70 kDa protein 4 HSP7C_HUMAN P11142 81 1 Heat shock cognate 71 kDa protein HTF4_HUMAN Q99081 23 1 Transcription factor 12 104 HTSF1_HUMAN O43719 AGGEPDSLGQQP 34 1 HIV Tat-specific factor 1 TDTPYEWDLDKK 105 HTSF1_HUMAN O43719 AGGEPDSLGQQP 34 1 HIV Tat-specific factor 1 TDTPYEWDLDKK AWFPK 106 HTSF1_HUMAN O43719 GASSSTANVEDV 81 1 HIV Tat-specific factor 1 HAR HTSF1_HUMAN O43719 40 1 HIV Tat-specific factor 1 HUWE1_HUMAN Q7Z6Z7 2360 1 E3 ubiquitin-protein ligase HUWE1 107 HUWE1_HUMAN Q7Z6Z7 GLPEEQPQTTK 3665 1 E3 ubiquitin-protein ligase HUWE1 108 HUWE1_HUMAN Q7Z6Z7 MNASPLVR 2474 1 E3 ubiquitin-protein ligase HUWE1 109 HUWE1_HUMAN Q7Z6Z7 SAVAISGADSR 2931 1 E3 ubiquitin-protein ligase HUWE1 HUWE1_HUMAN Q7Z6Z7 2018 1 E3 ubiquitin-protein ligase HUWE1 110 HUWE1_HUMAN Q7Z6Z7 SVLAVMPPDIAAE 3080 1 E3 ubiquitin-protein ligase AQALR HUWE1 I2BP2_HUMAN Q7Z5L9 496 1 Interferon regulatory factor 2-binding protein 2 I5P2_HUMAN P32019 264 1 Type II inositol-1,4,5- trisphosphate 5-phosphatase IASPP_HUMAN Q8WUF5 295 1 RelA-associated inhibitor 111 ICAL_HUMAN P20810 ALSSDFTCGSPTA 234 1 Calpastatin AGK 112 ICAL_HUMAN P20810 ALSSDFTCGSPTA 234 1 Calpastatin AGKK ICAL_HUMAN P20810 514 1 Calpastatin ICAL_HUMAN P20810 349 1 Calpastatin ICAL_HUMAN P20810 660 1 Calpastatin IF2BL_HUMAN A6NK07 119 2 Eukaryotic translation initiation factor 2 subunit 2- like protein IF2B_HUMAN P20042 119 Eukaryotic translation initiation factor 2 subunit 2 IF2P_HUMAN O60841 21 1 Eukaryotic translation initiation factor 5B IF2P_HUMAN O60841 21 1 Eukaryotic translation initiation factor 5B IF2P_HUMAN O60841 21 1 Eukaryotic translation initiation factor 5B IF4A2_HUMAN Q14240 22 1 Eukaryotic initiation factor 4A-II IF4A2_HUMAN Q14240 22 1 Eukaryotic initiation factor 4A-II IF4B_HUMAN P23588 60 1 Eukaryotic translation initiation factor 4B IF4B_HUMAN P23588 51 1 Eukaryotic translation initiation factor 4B IF4G1_HUMAN Q04637 533 1 Eukaryotic translation initiation factor 4 gamma 1 IF4G1_HUMAN Q04637 666 1 Eukaryotic translation initiation factor 4 gamma 1 IF4G1_HUMAN Q04637 415 1 Eukaryotic translation initiation factor 4 gamma 1 113 IF4G2_HUMAN P78344 SSSAPSKEQLEQEK 793 1 Eukaryotic translation initiation factor 4 gamma 2 114 IF4G2_HUMAN P78344 SSSAPSKEQLEQE 793 1 Eukaryotic translation KQLLLSFKPVMQK initiation factor 4 gamma 2 IF4G3_HUMAN O43432 479 1 Eukaryotic translation initiation factor 4 gamma 3 IF4G3_HUMAN O43432 479 1 Eukaryotic translation initiation factor 4 gamma 3 115 IF4H_HUMAN Q15056 SLKEALTYDGAL 94 1 Eukaryotic translation LGDR initiation factor 4H IF5A1_HUMAN P63241 97 1 Eukaryotic translation initiation factor 5A-1 IF5A1_HUMAN P63241 12 2 Eukaryotic translation initiation factor 5A-1 IF5AL_HUMAN Q6IS14 12 Eukaryotic translation initiation factor 5A-1-like IF5A1_HUMAN P63241 12 2 Eukaryotic translation initiation factor 5A-1 IF5AL_HUMAN Q6IS14 12 Eukaryotic translation initiation factor 5A-1-like IF5A1_HUMAN P63241 12 2 Eukaryotic translation initiation factor 5A-1 IF5AL_HUMAN Q6IS14 12 Eukaryotic translation initiation factor 5A-1-like IF5A1_HUMAN P63241 7 2 Eukaryotic translation initiation factor 5A-1 IF5AL_HUMAN Q6IS14 7 Eukaryotic translation initiation factor 5A-1-like IF5A1_HUMAN P63241 12 2 Eukaryotic translation initiation factor 5A-1 IF5AL_HUMAN Q6IS14 12 Eukaryotic translation initiation factor 5A-1-like IF5A1_HUMAN P63241 7 2 Eukaryotic translation initiation factor 5A-1 IF5AL_HUMAN Q6IS14 7 Eukaryotic translation initiation factor 5A-1-like IF5A1_HUMAN P63241 7 2 Eukaryotic translation initiation factor 5A-1 IF5AL_HUMAN Q6IS14 7 Eukaryotic translation initiation factor 5A-1-like IF5A1_HUMAN P63241 7 2 Eukaryotic translation initiation factor 5A-1 IF5AL_HUMAN Q6IS14 7 Eukaryotic translation initiation factor 5A-1-like IF5A2_HUMAN Q9GZV4 7 1 Eukaryotic translation initiation factor 5A-2 IF5A2_HUMAN Q9GZV4 7 1 Eukaryotic translation initiation factor 5A-2 IKBB_HUMAN Q15653 160 1 NF-kappa-B inhibitor beta 116 IKBL2_HUMAN Q96HA7 GLTPQLEEDEELQ 499 1 NF-kappa-B inhibitor-like GHLGR protein 2 117 IKBL2_HUMAN Q96HA7 GLTPQLEEDEELQ 499 1 NF-kappa-B inhibitor-like GHLGRR protein 2 IKZF1_HUMAN Q13422 368 1 DNA-binding protein Ikaros IKZF2_HUMAN Q9UKS7 8 1 Zinc finger protein Helios IKZF5_HUMAN Q9H5V7 226 1 Zinc finger protein Pegasus 118 ILF3_HUMAN Q12906 GSGIYDPCEKEAT 288 1 interleukin enhancer-binding DAIGHLDR factor 3 ILF3_HUMAN Q12906 440 1 Interleukin enhancer-binding factor 3 ILF3_HUMAN Q12906 440 1 Interleukin enhancer-binding factor 3 ILKAP_HUMAN Q9H0C8 40 1 Integrin-linked kinase- associated serine/threonine phosphatase 2C IMA1_HUMAN P52294 65 1 Importin subunit alpha-1 IMA1_HUMAN P52294 65 1 Importin subunit alpha-1 IMA7_HUMAN O60684 70 1 Importin subunit alpha-7 119 IMDH2_HUMAN P12268 CFLEEIMTK 173 1 Inosine-5′-monophosphate dehydrogenase 2 IN80D_HUMAN Q53TQ3 679 1 INO80 complex subunit D 120 INF2_HUMAN Q27J81 AVTPGPQPTLEQL 1052 1 Inverted formin-2 EEGGPRPLER 121 INF2_HUMAN Q27J81 AVTPGPQPTLEQL 1052 1 Inverted formin-2 EEGGPRPLERR INF2_HUMAN Q27J81 1147 1 Inverted formin-2 IPO9_HUMAN Q96P70 964 1 Importin-9 IQEC1_HUMAN Q6DN90 235 1 IQ motif and SEC7 domain- containing protein 1 122 IQGA1_HUMAN P46940 GLGVARPHYGSV 9 1 Ras GTPase-activating-like LDNER protein IQGAP1 123 IQGA1_HUMAN P46940 GLGVARPHYGSV 9 1 Ras GTPase-activating-like LDNERLTAEEMD protein IQGAP1 ER IRF2_HUMAN P14316 238 1 Interferon regulatory factor 2 IRS4_HUMAN O14654 717 1 Insulin receptor substrate 4 124 ISY1_HUMAN Q9ULR0 GVIVPLEQEYEK 168 1 Pre-mRNA-splicing factor ISY1 homolog 125 ISY1_HUMAN Q9ULR0 GVIVPLEQEYEKK 168 1 Pre-mRNA-splicing factor ISY1 homolog IWS1_HUMAN Q96ST2 348 1 Protein IWS1 homolog IWS1_HUMAN Q96ST2 348 1 Protein IWS1 homolog 126 JHD3C_HUMAN Q9H3R0 GAEVPNPDSVTD 397 1 JmjC domain-containing DLK histone demethylation protein 3C 127 JHD3C_HUMAN Q9H3R0 GAEVPNPDSVTD 397 1 JmjC domain-containing DLKVSEK histone demethylation protein 3C JIP4_HUMAN O60271 214 1 C-jun-amino-terminal kinase-interacting protein 4 JIP4_HUMAN O60271 6 1 C-jun-amino-terminal kinase-interacting protein 4 JIP4_HUMAN O60271 6 1 C-jun-amino-terminal kinase-interacting protein 4 JIP4_HUMAN O60271 285 1 C-jun-amino-terminal kinase-interacting protein 4 JKIP1_HUMAN Q96N16 18 1 Janus kinase and microtubule-interacting protein 1 128 JKIP1_HUMAN Q96N16 AVQMANEELR 18 1 Janus kinase and microtubule-interacting protein 1 JMY_HUMAN Q8N9B5 723 1 Junction-mediating and - regulatory protein JMY_HUMAN Q8N9B5 723 1 Junction-mediating and - regulatory protein 129 JOSD3_HUMAN Q9H5J8 HVTSDAVELANR 11 1 Protein JOSD3 130 JSPR1_HUMAN Q96MG2 GGLGSCQALEDH 13 1 Junctional sarcoplasmic SALAETQEDR reticulum protein 1 K0174_HUMAN P53990 198 1 Uncharacterized protein KIAA0174 K0174_HUMAN P53990 198 1 Uncharacterized protein KIAA0174 K0232_HUMAN Q92628 557 1 Uncharacterized protein KIAA0232 K0515_HUMAN Q5JSZ5 1083 1 Uncharacterized protein KIAA0515 K0515_HUMAN Q5JSZ5 1236 1 Uncharacterized protein KIAA0515 K0831_HUMAN Q6ZNE5 29 1 Uncharacterized protein KIAA0831 K0831_HUMAN Q6ZNE5 227 1 Uncharacterized protein KIAA0831 K1462_HUMAN Q9P266 1180 1 Uncharacterized protein KIAA1462 131 K1543_HUMAN Q9P1Y5 GSPAGAEDSLEEE 862 1 Uncharacterized protein ASSEGEPR KIAA1543 132 K1627_HUMAN Q9HCE5 SIGAVLNSKDEQR 30 1 Methyltransferase-like protein KIAA1627 133 K1627_HUMAN Q9HCE5 SIGAVLNSKDEQR 30 1 Methyltransferase-like EIAETR protein KIAA1627 134 K1627_HUMAN Q9HCE5 SIGAVLNSK 30 1 Methyltransferase-like protein KIAA1627 K1704_HUMAN Q8IXQ4 89 1 Uncharacterized protein KIAA1704 135 K1967_HUMAN Q8N163 AGAEPITADSDPA 293 1 Protein KIAA1967 YSSK K1967_HUMAN Q8N163 769 1 Protein KIAA1967 K1967_HUMAN Q8N163 619 1 Protein KIAA1967 136 KHDR1_HUMAN Q07666 ATVGGPAPTPLLP 76 1 KH domain-containing, PSATASVK RNA-binding, signal transduction-associated protein 1 KI67_HUMAN P46013 2148 1 Antigen KI-67 KI67_HUMAN P46013 411 1 Antigen KI-67 KI67_HUMAN P46013 174 1 Antigen KI-67 KIF15_HUMAN Q9NS87 1134 1 Kinesin-like protein KIF15 KKCC1_HUMAN Q8N5S9 33 1 Calcium/calmodulin- dependent protein kinase Kinase 1 KLF12_HUMAN Q9Y4X4 74 1 Krueppel-like factor 12 137 KPYM_HUMAN P14618 GADCIMLSGETA 355 1 Pyruvate kinase isozymes KGDYPLEAVR M1/M2 138 KPYM_HUMAN P14618 GADCIMLSGETAK 355 2 Pyruvate kinase isozymes   M1/M2 138 KPYR_HUMAN P30613 GADCIMLSGETAK 398 Pyruvate kinase isozymes R/L KRI1_HUMAN Q8N9T8 313 1 Protein KRI1 homolog 139 KRR1_HUMAN Q13601 GWKEPAFSK 39 1 KRR1 small subunit processome component homolog 140 KRR1_HUMAN Q13601 GWKEPAFSKEDN 39 1 KRR1 small subunit PR processome component homolog KS6A4_HUMAN O75676 378 1 Ribosomal protein S6 kinase alpha-4 KU86_HUMAN P13010 456 1 ATP-dependent DNA helicase 2 subunit 2 KU86_HUMAN P13010 456 1 ATP-dependent DNA helicase 2 subunit 2 KU86_HUMAN P13010 557 1 ATP-dependent DNA helicase 2 subunit 2 LAGE3_HUMAN Q14657 29 1 L antigen family member 3 LAMB1_HUMAN P07942 1359 1 Laminin subunit beta-1 LAP2A_HUMAN P42166 487 1 Lamina-associated polypeptide 2, isoform alpha LAP2A_HUMAN P42166 442 1 Lamina-associated polypeptide 2, isoform alpha 141 LAP4_HUMAN Q14160 AALEVSPGVIANP 1198 1 Protein LAP4 FAAGIGHR LAP4_HUMAN Q14160 502 1 Protein LAP4 LAP4_HUMAN Q14160 636 1 Protein LAP4 142 LARP1_HUMAN Q6PKG0 AINWPTPGEIAHK 173 1 La-related protein 1 143 LARP1_HUMAN Q6PKG0 FSQLLNCPEFVPR 496 1 La-related protein 1 144 LARP4_HUMAN Q71RC2 GLNQTTIPVSPPST 574 1 La-related protein 4 TKPSR LARP5_HUMAN Q92615 136 1 La-related protein 5 LAT_HUMAN O43561 168 1 Linker for activation of T- cells family member 1 145 LCAP_HUMAN Q9UIQ6 LAKEPCLHPLEPD 30 1 Leucyl-cystinyl EVEYEPR aminopeptidase LCORL_HUMAN Q8N3X6 230 2 Ligand-dependent nuclear receptor corepressor-like protein LCOR_HUMAN Q96JN0 81 Ligand-dependent corepressor LIMA1_HUMAN Q9UHB6 346 1 LIM domain and actin- binding protein 1 LIN37_HUMAN Q96GY3 24 1 Protein lin-37 homolog LIN7C_HUMAN Q9NUP9 63 1 Lin-7 homolog C 146 LIPA1_HUMAN Q13136 GVLDINHEQENTP 219 1 Liprin-alpha-1 STSGK 147 LIPA1_HUMAN Q13136 GVLDINHEQENTP 219 1 Liprin-alpha-1 STSGKR LIPB2_HUMAN Q8ND30 32 1 Liprin-beta-2 LMNB1_HUMAN P20700 147 1 Lamin-B1 LMO7_HUMAN Q8WWI1 963 1 LIM domain only protein 7 LMTK2_HUMAN Q8IWU2 901 1 Serine/threonine-protein kinase LMTK2 LNP_HUMAN Q9C0E8 369 1 Protein lunapark LPP_HUMAN Q93052 404 1 Lipoma-preferred partner LPP_HUMAN Q93052 404 1 Lipoma-preferred partner LRBA_HUMAN P50851 1757 1 Lipopolysaccharide- responsive and beige-like anchor protein 148 LRBA_HUMAN P50851 SAQASDMGGESP 1757 1 Lipopolysaccharide- GSR responsive and beige-like anchor protein LRBA_HUMAN P50851 1785 1 Lipopolysaccharide- responsive and beige-like anchor protein LRBA_HUMAN P50851 1785 1 Lipopolysaccharide- responsive and beige-like anchor protein 149 LRC47_HUMAN Q8N1G4 AVSGQLPDPTTNP 526 1 Leucine-rich repeat- SAGK containing protein 47 150 LRC47_HUMAN Q8N1G4 AVSGQLPDPTTNP 526 1 Leucine-rich repeat- SAGKDGPSLLVV containing protein 47 EQVR LRCH1_HUMAN Q9Y2L9 406 1 Leucine-rich repeat and calponin homology domain- containing protein 1 LRCH1_HUMAN Q9Y2L9 406 1 Leucine-rich repeat and calponin homology domain- containing protein 1 LRCH2_HUMAN Q5VUJ6 604 1 Leucine-rich repeat and calponin homology domain- containing protein 2 LRCH3_HUMAN Q96II8 643 1 Leucine-rich repeat and calponin homology domain- containing protein 3 LRCH4_HUMAN O75427 359 1 Leucine-rich repeat and calponin homology domain- containing protein 4 151 LRMP_HUMAN Q12912 SVVSPLPVTTVK 182 1 Lymphoid-restricted membrane protein LRRF1_HUMAN Q32MZ4 416 1 Leucine-rich repeat flightless-interacting protein 1 LRRF2_HUMAN Q9Y608 532 1 Leucine-rich repeat flightless-interacting protein 2 LSM11_HUMAN P83369 306 1 U7 snRNA-associated Sm- like protein LSm11 LSM3_HUMAN P62310 7 1 U6 snRNA-associated Sm- like protein LSm3 LSP1_HUMAN P33241 103 1 Lymphocyte-specific protein 1 152 LTV1_HUMAN Q96GA3 SAGLLSDEDCMS 206 1 Protein LTV1 homolog VPGKTHR LYRIC_HUMAN Q86UE4 184 1 Protein LYRIC 153 M6PBP_HUMAN O60664 GFDVASVQQQR 220 1 Mannose-6-phosphate receptor-binding protein 1 M6PBP_HUMAN O60664 10 1 Mannose-6-phosphate receptor-binding protein 1 M6PBP_HUMAN O60664 223 1 Mannose-6-phosphate receptor-binding protein 1 MA7D1_HUMAN Q3KQU3 571 1 MAP7 domain-containing protein 1 154 MA7D1_HUMAN Q3KQU3 AAVLTSPPAPAPP 571 1 MAP7 domain-containing VTPSKPMAGTTD protein 1 REEATR MACF1_HUMAN Q9UPN3 1524 1 Microtubule-actin cross- linking factor 1, isoforms 1/2/3/5 MACF1_HUMAN Q9UPN3 3021 2 Microtubule-actin cross- linking factor 1, isoforms 1/2/3/5 MACF4_HUMAN Q96PK2 3523 Microtubule-actin cross- linking factor 1, isoform 4 MACF1_HUMAN Q9UPN3 3021 2 Microtubule-actin cross- linking factor 1, isoforms 1/2/3/5 MACF4_HUMAN Q96PK2 3523 Microtubule-actin cross- linking factor 1, isoform 4 155 MACF1_HUMAN Q9UPN3 GYMGVNQAPEKL 1727 2 Microtubule-actin cross- DKQCEMMK linking factor 1, isoforms 1/2/3/5 155 MACF4_HUMAN Q96PK2 GYMGVNQAPEKL 2229 Microtubule-actin cross- DKQCEMMK linking factor 1, isoform 4 MACF1_HUMAN Q9UPN3 1727 2 Microtubule-actin cross- linking factor 1, isoforms 1/2/3/5 MACF4_HUMAN Q96PK2 2229 Microtubule-actin cross- linking factor 1, isoform 4 MACF1_HUMAN Q9UPN3 1727 2 Microtubule-actin cross- linking factor 1, isoforms 1/2/3/5 MACF4_HUMAN Q96PK2 2229 Microtubule-actin cross- linking factor 1, isoform 4 156 MACF1_HUMAN Q9UPN3 GYMGVNQAPEKL 1727 2 Microtubule-actin cross- DK linking factor 1, isoforms 1/2/3/5 156 MACF4_HUMAN Q96PK2 GYMGVNQAPEKL 2229 Microtubule-actin cross- DK linking factor 1, isoform 4 157 MACF1_HUMAN Q9UPN3 GYMGVNQAPEK 1727 2 Microtubule-actin cross- linking factor 1, isoforms 1/2/3/5 157 MACF4_HUMAN Q96PK2 GYMGVNQAPEK 2229 Microtubule-actin cross- linking factor 1, isoform 4 158 MADD_HUMAN Q8WXG6 SVIGVSPAVMIR 1178 1 MAP kinase-activating death domain protein MAGD1_HUMAN Q9Y5V3 223 1 Melanoma-associated antigen D1 159 MAGG1_HUMAN Q96MG7 GFAEEAPSTSR 42 1 Melanoma-associated antigen G1 160 MAGG1_HUMAN Q96MG7 GFAEEAPSTSRGP 42 1 Melanoma-associated GGSQGSQGPSPQ antigen G1 GAR MAOM_HUMAN P23368 380 1 NAD-dependent malic enzyme, mitochondrial 161 MAP1A_HUMAN P78559 SVVAAVQEGAAE 1885 1 Microtubule-associated LEGGPYSPLGK protein 1A 162 MAP1A_HUMAN P78559 SVVAAVQEGAAE 1885 1 Microtubule-associated LEGGPYSPLGKD protein 1A YR 163 MAP1A_HUMAN P78559 SVVAAVQEGAAE 1885 1 Microtubule-associated LEGGPYSPLGKD protein 1A YRK MAP4_HUMAN P27816 9 1 Microtubule-associated protein 4 MAP4_HUMAN P27816 9 1 Microtubule-associated protein 4 MAP4_HUMAN P27816 250 1 Microtubule-associated protein 4 MAP4_HUMAN P27816 152 1 Microtubule-associated protein 4 MAP4_HUMAN P27816 328 1 Microtubule-associated protein 4 MAP4_HUMAN P27816 47 1 Microtubule-associated protein 4 MAP9_HUMAN Q49MG5 120 1 Microtubule-associated protein 9 MARE1_HUMAN Q15691 117 1 Microtubule-associated protein RP/EB family member 1 MARK1_HUMAN Q9P0L2 23 1 Serine/threonine-protein kinase MARK1 164 MATR3_HUMAN P43243 GQSDENKDDYTIP 764 1 Matrin-3 DEYR 165 MATR3_HUMAN P43243 LANLGDVASDGK 681 1 Matrin-3 166 MATR3_HUMAN P43243 LANLGDVASDGKK 681 1 Matrin-3 167 MATR3_HUMAN P43243 SFDDRGPSLNPVL 188 1 Matrin-3 DYDHGSR 168 MATR3_HUMAN P43243 YYTTTPALVFGKP 453 1 Matrin-3 VR MATR3_HUMAN P43243 704 1 Matrin-3 169 MATR3_HUMAN P43243 LANLGDVASDGK 681 1 Matrin-3 KEPSDK MAVS_HUMAN Q7Z434 491 1 Mitochondrial antiviral- signaling protein MAVS_HUMAN Q7Z434 491 1 Mitochondrial antiviral- signaling protein MAX_HUMAN P61244 49 1 Protein max MBB1A_HUMAN Q9BQG0 750 1 Myb-binding protein 1A MCM2_HUMAN P49736 89 1 DNA replication licensing factor MCM2 MCM2_HUMAN P49736 69 1 DNA replication licensing factor MCM2 170 MCM3_HUMAN P25205 SYDPYDFSDTEEE 704 1 DNA replication licensing MPQVHTPK factor MCM3 171 MCM4_HUMAN P33991 GAAAEDIVASEQS 133 1 DNA replication licensing LGQK factor MCM4 172 MCM5_HUMAN P33992 SFGGDAQADEGQ 14 1 DNA replication licensing ARK factor MCM5 173 MCM5_HUMAN P33992 SFGGDAQADEGQ 14 1 DNA replication licensing AR factor MCM5 174 MCM6_HUMAN Q14566 GYETEGIRGLR 275 1 DNA replication licensing factor MCM6 175 MCM6_HUMAN Q14566 GYETEGIR 275 1 DNA replication licensing factor MCM6 MDC1_HUMAN Q14676 1036 1 Mediator of DNA damage checkpoint protein 1 MDC1_HUMAN Q14676 1036 1 Mediator of DNA damage checkpoint protein 1 MDN1_HUMAN Q9NU22 5128 1 Midasin MED14_HUMAN O60244 995 1 Mediator of RNA polymerase II transcription subunit 14 MED1_HUMAN Q15648 931 1 Mediator of RNA polymerase II transcription subunit 1 MED1_HUMAN Q15648 1485 1 Mediator of RNA polymerase II transcription subunit 1 MED26_HUMAN O95402 408 1 Mediator of RNA polymerase II transcription subunit 26 MEF2C_HUMAN Q06413 106 1 Myocyte-specific enhancer factor 2C MEF2C_HUMAN Q06413 106 1 Myocyte-specific enhancer factor 2C METK2_HUMAN P31153 40 1 S-adenosylmethionine synthetase isoform type-2 MEX3B_HUMAN Q6ZN04 355 1 RNA-binding protein MEX3B MGAP_HUMAN Q8IWI9 681 1 MAX gene-associated protein MGAP_HUMAN Q8IWI9 340 1 MAX gene-associated protein MGAP_HUMAN Q8IWI9 340 1 MAX gene-associated protein MGAP_HUMAN Q8IWI9 572 1 MAX gene-associated protein MIA3_HUMAN Q5JRA6 710 1 Melanoma inhibitory activity protein 3 MIER1_HUMAN Q8N108 52 1 Mesoderm induction early response protein 1 MINT_HUMAN Q96T58 1575 1 Msx2-interacting protein MINT_HUMAN Q96T58 2008 1 Msx2-interacting protein MINT_HUMAN Q96T58 2860 1 Msx2-interacting protein MISSL_HUMAN Q8NDC0 10 1 MAPK-interacting and spindle-stabilizing protein- like 176 MKL1_HUMAN Q969V6 ALSPEQPASHESQ 122 1 MKL/myocardin-like protein 1 GSVPSPLEAR MKL2_HUMAN Q9ULH7 183 1 MKL/myocardin-like protein 2 177 MLL2_HUMAN O14686 ALYVACQGQPK 387 1 Histone-lysine N- methyltransferase MLL2 MLL2_HUMAN O14686 1866 1 Histone-lysine N- methyltransferase MLL2 MLL3_HUMAN Q8NEZ4 2189 1 Histone-lysine N- methyltransferase MLL3 MOBL3_HUMAN Q9Y3A3 35 1 Mps one binder kinase activator-like 3 MOES_HUMAN P26038 115 1 Moesin MORC3_HUMAN Q14149 665 1 MORC family CW-type zinc finger protein 3 MORC3_HUMAN Q14149 752 1 MORC family CW-type zinc finger protein 3 MOT1_HUMAN P53985 470 1 Monocarboxylate transporter 1 MP2K1_HUMAN Q02750 283 1 Dual specificity mitogen- activated protein kinase kinase 1 178 MP2K1_HUMAN Q02750 GSAVNGTSSAET 17 1 Dual specificity mitogen- NLEALQK activated protein kinase kinase 1 179 MP2K1_HUMAN Q02750 GSAVNGTSSAET 17 1 Dual specificity mitogen- NLEALQKK activated protein kinase kinase 1 180 MPP10_HUMAN O00566 AALLAPEEIKEK 546 1 U3 small nucleolar ribonucleoprotein protein MPP10 181 MPP10_HUMAN O00566 AALLAPEEIK 546 1 U3 small nucleolar ribonucleoprotein protein MPP10 MPP8_HUMAN Q99549 20 1 M-phase phosphoprotein 8 MPP8_HUMAN Q99549 502 1 M-phase phosphoprotein 8 MPP8_HUMAN Q99549 517 1 M-phase phosphoprotein 8 182 MRP_HUMAN P49006 AIEPAPPSQGAEAK 64 1 MARCKS-related protein MSPD2_HUMAN Q8NHP6 275 1 Motile sperm domain- containing protein 2 MTA70_HUMAN Q86U44 335 1 N6-adenosine- methyltransferase 70 kDa subunit MYH10_HUMAN P35580 1310 1 Myosin-10 183 MYH10_HUMAN P35580 TTAAQQELR 1161 1 Myosin-10 184 MYH11_HUMAN P35749 STATQQELR 1161 1 Myosin-11 MYH9_HUMAN P35579 1376 1 Myosin-9 185 MYH9_HUMAN P35579 STAAQQELR 1154 1 Myosin-9 186 MYO9B_HUMAN Q13459 SLTSDKASVPIVL 1704 1 Myosin-IXb EK MYPT1_HUMAN O14974 886 1 Protein phosphatase 1 regulatory subunit 12A N4BP1_HUMAN O75113 491 1 NEDD4-binding protein 1 NACA_HUMAN Q13765 43 1 Nascent polypeptide- associated complex subunit alpha NACA_HUMAN Q13765 43 1 Nascent polypeptide- associated complex subunit alpha NADAP_HUMAN Q9BWU0 538 1 Kanadaptin NADAP_HUMAN Q9BWU0 538 1 Kanadaptin NADAP_HUMAN Q9BWU0 538 1 Kanadaptin NAG_HUMAN A2RRP1 637 1 Neuroblastoma-amplified gene protein NAG_HUMAN A2RRP1 637 1 Neuroblastoma-amplified gene protein NAIF1_HUMAN Q69YI7 103 1 Nuclear apoptosis-inducing factor 1 NARF_HUMAN Q9UHQ1 292 1 Nuclear prelamin A recognition factor NARF_HUMAN Q9UHQ1 273 1 Nuclear prelamin A recognition factor 187 NASP_HUMAN P49321 KIEDVPAPSTSAD 20 1 Nuclear autoantigenic sperm KVESLDVDSEAK protein NASP_HUMAN P49321 33 1 Nuclear autoantigenic sperm protein NASP_HUMAN P49321 33 1 Nuclear autoantigenic sperm protein 188 NCK1_HUMAN P16333 SASPADDSFVDPG 89 1 Cytoplasmic protein NCK1 ER NCOA3_HUMAN Q9Y6Q9 1013 1 Nuclear receptor coactivator 3 NCOA5_HUMAN Q9HCD5 381 1 Nuclear receptor coactivator 5 NCOA5_HUMAN Q9HCD5 154 1 Nuclear receptor coactivator 5 NCOA6_HUMAN Q14686 1462 1 Nuclear receptor coactivator 6 NCOR1_HUMAN O75376 1827 1 Nuclear receptor corepressor 1 NCOR1_HUMAN O75376 386 1 Nuclear receptor corepressor 1 NCOR1_HUMAN O75376 556 1 Nuclear receptor corepressor 1 189 NCOR1_HUMAN O75376 AAASAPQMDVSK 1827 1 Nuclear receptor corepressor 1 NCOR1_HUMAN O75376 386 1 Nuclear receptor corepressor 1 NCOR1_HUMAN O75376 556 1 Nuclear receptor corepressor 1 NCOR2_HUMAN Q9Y618 378 1 Nuclear receptor corepressor 2 NCOR2_HUMAN Q9Y618 1927 1 Nuclear receptor corepressor 2 NDRG1_HUMAN Q92597 10 1 Protein NDRG1 190 NEB2_HUMAN Q96SB3 GTSLVGVTQSFA 552 1 Neurabin-2 ASVLR 191 NED4L_HUMAN Q96PU5 AVAEQGHLPPPSA 346 1 E3 ubiquitin-protein ligase PAGR NEDD4-like NEDD1_HUMAN Q8NHV4 435 1 Protein NEDD1 NEDD4_HUMAN P46934 280 1 E3 ubiquitin-protein ligase NEDD4 NEK1_HUMAN Q96PY6 950 1 Serine/threonine-protein kinase Nek1 NEK4_HUMAN P51957 381 1 Serine/threonine-protein kinase Nek4 NEK9_HUMAN Q8TD19 842 1 Serine/threonine-protein kinase Nek9 NELFA_HUMAN Q9H3P2 300 1 Negative elongation factor A NFAC1_HUMAN O95644 111 1 Nuclear factor of activated T- cells, cytoplasmic 1 NFAC2_HUMAN Q13469 67 1 Nuclear factor of activated T- cells, cytoplasmic 2 NFKB2_HUMAN Q00653 11 1 Nuclear factor NF-kappa-B p100 subunit NFRKB_HUMAN Q6P4R8 497 1 Nuclear factor related to kappa-B-binding protein NFRKB_HUMAN Q6P4R8 6 1 Nuclear factor related to kappa-B-binding protein NHERF_HUMAN O14745 5 1 Ezrin-radixin-moesin- binding phosphoprotein 50 NIPA_HUMAN Q86WB0 450 1 Nuclear-interacting partner of ALK NIPA_HUMAN Q86WB0 296 1 Nuclear-interacting partner of ALK NIPBL_HUMAN Q6KC79 473 1 Nipped-B-like protein NIPBL_HUMAN Q6KC79 473 1 Nipped-B-like protein NKTR_HUMAN P30414 960 1 NK-tumor recognition protein NOL1_HUMAN P46087 231 1 Putative RNA methyltransferase NOL1 NOL1_HUMAN P46087 208 1 Putative RNA methyltransferase NOL1 192 NOL1_HUMAN P46087 GGLQINVDEEPFV 208 1 Putative RNA LPPAGEMEQDAQ methyltransferase NOL1 APDLQR 193 NOL1_HUMAN P46087 GGLQINVDEEPFV 208 1 Putative RNA LPPAGEMEQDAQ methyltransferase NOL1 APDLQRVHKR 194 NOL5_HUMAN Q9Y2X3 GLIPGVEPR 125 1 Nucleolar protein 5 NOP14_HUMAN P78316 320 1 Nucleolar protein 14 NOP14_HUMAN P78316 320 1 Nucleolar protein 14 195 NP1L1_HUMAN P55209 GLVETPTGYIESL 58 1 Nucleosome assembly PR protein 1-like 1 196 NP1L1_HUMAN P55209 GLVETPTGYIESL 58 1 Nucleosome assembly PRVVKR protein 1-like 1 NP1L1_HUMAN P55209 184 1 Nucleosome assembly protein 1-like 1 197 NP1L4_HUMAN Q99733 GVPSDSVEAAK 9 1 Nucleosome assembly protein 1-like 4 198 NP1L4_HUMAN Q99733 GVPSDSVEAAKN 9 1 Nucleosome assembly ASNTEK protein 1-like 4 NP1L4_HUMAN Q99733 9 1 Nucleosome assembly protein 1-like 4 199 NP1L4_HUMAN Q99733 GVPSDSVEAAKN 9 1 Nucleosome assembly ASNTEKLTDQVM protein 1-like 4 QNPR 200 NP1L4_HUMAN Q99733 NVPHTPSSYIETLPK 47 1 Nucleosome assembly protein 1-like 4 NP60_HUMAN Q49A26 256 1 Nuclear protein NP60 NPAT_HUMAN Q14207 734 1 Protein NPAT NPM_HUMAN P06748 7 1 Nucleophosmin NPM_HUMAN P06748 4 1 Nucleophosmin NS1BP_HUMAN Q9Y6Y0 239 1 Influenza virus NS1A- binding protein NSBP1_HUMAN P82970 58 1 Nucleosome-binding protein 1 201 NSUN2_HUMAN Q08J23 GQKVEVPQPLSW 109 1 tRNA (cytosine-5-)- YPEELAWHTNLSR methyltransferase NSUN2 202 NSUN2_HUMAN Q08J23 GQKVEVPQPLSW 109 1 tRNA (cytosine-5-)- YPEELAWHTNLS methyltransferase NSUN2 RK NSUN2_HUMAN Q08J23 500 1 tRNA (cytosine-5-)- methyltransferase NSUN2 NSUN2_HUMAN Q08J23 500 1 tRNA (cytosine-5-)- methyltransferase NSUN2 NSUN2_HUMAN Q08J23 665 1 tRNA (cytosine-5-)- methyltransferase NSUN2 NU153_HUMAN P49790 359 1 Nuclear pore complex protein Nup153 NUCB2_HUMAN P80303 259 1 Nucleobindin-2 NUCB2_HUMAN P80303 238 1 Nucleobindin-2 NUCKS_HUMAN Q9H1E3 30 3 Nuclear ubiquitous casein and cyclin-dependent kinases substrate NUCL_HUMAN P19338 637 1 Nucleolin NUDC3_HUMAN Q8IVD9 126 1 NudC domain-containing protein 3 NUDC3_HUMAN Q8IVD9 126 1 NudC domain-containing protein 3 NUDC3_HUMAN Q8IVD9 120 1 NudC domain-containing protein 3 NUFP2_HUMAN Q7Z417 452 1 Nuclear fragile X mental retardation-interacting protein 2 NUMA1_HUMAN Q14980 1748 1 Nuclear mitotic apparatus protein 1 NUMA1_HUMAN Q14980 1748 1 Nuclear mitotic apparatus protein 1 NUMA1_HUMAN Q14980 1830 1 Nuclear mitotic apparatus protein 1 203 NUP43_HUMAN Q8NFH3 GGFEGDHQLLCDIR 59 1 Nucleoporin Nup43 NUP50_HUMAN Q9UKX7 127 1 Nucleoporin 50 kDa 204 NUP93_HUMAN Q8N1F7 FTQESEPSYISDV 158 1 Nuclear pore complex GPPGR protein Nup93 205 ODPB_HUMAN P11177 AINQGMDEELER 38 1 Pyruvate dehydrogenase E1 DEK component subunit beta, mitochondrial OFD1_HUMAN O75665 854 1 Oral-facial-digital syndrome 1 protein ORAV1_HUMAN Q8WV07 10 1 Oral cancer overexpressed protein 1 OSBL8_HUMAN Q9BZF1 807 1 Oxysterol-binding protein- related protein 8 OTU6B_HUMAN Q8N6M0 81 1 OTU domain-containing protein 6B OTUD4_HUMAN Q01804 10 1 OTU domain-containing protein 4 OXR1_HUMAN Q8N573 450 1 Oxidation resistance protein 1 OXR1_HUMAN Q8N573 450 1 Oxidation resistance protein 1 P4R3A_HUMAN Q6IN85 693 1 Serine/threonine-protein phosphatase 4 regulatory subunit 3A P66B_HUMAN Q8WXI9 345 1 Transcriptional repressor p66-beta 206 PA24A_HUMAN P47712 AAVADPDEFER 523 1 Cytosolic phospholipase A2 207 PABP2_HUMAN Q86U42 GAIEDPELEAIK 112 1 Polyadenylate-binding protein 2 208 PABP2_HUMAN Q86U42 GAIEDPELEAIKAR 112 1 Polyadenylate-binding protein 2 PAIRB_HUMAN Q8NC51 338 1 Plasminogen activator inhibitor 1 RNA-binding protein PAK1_HUMAN Q13153 91 2 Serine/threonine-protein PAK2_HUMAN Q13177 90 kinase PAK 1 Serine/threonine-protein kinase PAK 2 PAK2_HUMAN Q13177 149 1 Serine/threonine-protein kinase PAK 2 PALLD_HUMAN Q8WX93 433 1 Palladin PARG_HUMAN Q86W56 257 1 Poly(ADP-ribose) glycohydrolase PARP1_HUMAN P09874 215 1 Poly [ADP-ribose] polymerase 1 PARP1_HUMAN P09874 215 1 Poly [ADP-ribose] polymerase 1 PARP1_HUMAN P09874 215 1 Poly [ADP-ribose] polymerase 1 PARP1_HUMAN P09874 73 1 Poly [ADP-ribose] polymerase 1 PAWR_HUMAN Q96IZ0 132 1 PRKC apoptosis WT1 regulator protein PAXI_HUMAN P49023 103 1 Paxillin PAXI_HUMAN P49023 6 1 Paxillin PAXI_HUMAN P49023 336 1 Paxillin PB1_HUMAN Q86U86 22 1 Protein polybromo-1 PCBP1_HUMAN Q15365 204 1 Poly(rC)-binding protein 1 209 PCBP1_HUMAN Q15365 AYSIQGQHTISPL 221 1 Poly(rC)-binding protein 1 DLAK 210 PCBP1_HUMAN Q15365 ASTQTTHELTIPN 276 1 Poly(rC)-binding protein 1 NLIGCIIGR PCBP2_HUMAN Q15366 283 1 Poly(rC)-binding protein 2 PCF11_HUMAN O94913 1289 1 Pre-mRNA cleavage complex 2 protein Pcf11 211 PCM1_HUMAN Q15154 GRGEPAMESSQIV 194 1 Pericentriolar material 1 SR protein PCM1_HUMAN Q15154 1552 1 Pericentriolar material 1 protein PCNT_HUMAN O95613 81 1 Pericentrin 212 PDIP3_HUMAN Q9BY77 AYTAPALPSSIR 235 1 Polymerase delta-interacting protein 3 PDLI1_HUMAN O00151 55 1 PDZ and LIM domain protein 1 PDXD1_HUMAN Q6P996 585 1 Pyridoxal-dependent decarboxylase domain- containing protein 1 PEBB_HUMAN Q13951 121 1 Core-binding factor subunit beta PFTK1_HUMAN O94921 57 1 Serine/threonine-protein kinase PFTAIRE-1 213 PGK1_HUMAN P00558 CVGPEVEK 99 1 Phosphoglycerate kinase 1 214 PGK1_HUMAN P00558 CVGPEVEKACAN 99 1 Phosphoglycerate kinase 1 PAAGSVILLENLR PGK1_HUMAN P00558 286 1 Phosphoglycerate kinase 1 PGK1_HUMAN P00558 69 1 Phosphoglycerate kinase 1 PGK1_HUMAN P00558 160 2 Phosphoglycerate kinase 1 PGK2_HUMAN P07205 160 Phosphoglycerate kinase 2 PHAR4_HUMAN Q8IZ21 21 1 Phosphatase and actin regulator 4 PHF3_HUMAN Q92576 1627 1 PHD finger protein 3 PHF3_HUMAN Q92576 1100 1 PHD finger protein 3 PHF3_HUMAN Q92576 1158 1 PHD finger protein 3 PHF3_HUMAN Q92576 1398 1 PHD finger protein 3 PHTNS_HUMAN Q6NYC8 496 1 Phostensin 215 PI4KB_HUMAN Q9UBF8 SITSQESKEPVFIA 489 1 Phosphatidylinositol 4-kinase AGDIR beta 216 PI4KB_HUMAN Q9UBF8 SITSQESKEPVFIA 489 1 Phosphatidylinositol 4-kinase AGDIRR beta 217 PIAS1_HUMAN O75925 GHPASSPLLPVSL 101 1 E3 SUMO-protein ligase LGPK PIAS1 PICAL_HUMAN Q13492 277 1 Phosphatidylinositol-binding clathrin assembly protein PITM1_HUMAN O00562 379 1 Membrane-associated phosphatidylinositol transfer protein 1 PJA2_HUMAN O43164 87 1 E3 ubiquitin-protein ligase Praja2 PKHG1_HUMAN Q9ULL1 436 1 Pleckstrin homology domain-containing family G member 1 PKP4_HUMAN Q99569 804 1 Plakophilin-4 PLCG1_HUMAN P19174 771 1 1-phosphatidylinositol-4,5- bisphosphate phosphodiesterase gamma-1 PLDN_HUMAN Q9UL45 11 1 Pallidin POGZ_HUMAN Q7Z3K3 28 1 Pogo transposable element with ZNF domain POMP_HUMAN Q9Y244 13 1 Proteasome maturation protein PP1RA_HUMAN Q96QC0 377 1 Serine/threonine-protein phosphatase 1 regulatory subunit 10 PP1RA_HUMAN Q96QC0 294 1 Serine/threonine-protein phosphatase 1 regulatory subunit 10 PP1RA_HUMAN Q96QC0 367 1 Serine/threonine-protein phosphatase 1 regulatory subunit 10 PP4R1_HUMAN Q8TF05 445 1 Serine/threonine-protein phosphatase 4 regulatory subunit 1 PPIA_HUMAN P62937 10 1 Peptidyl-prolyl cis-trans isomerase A 218 PPIL4_HUMAN Q8WUA2 ADIKPPENVLFVCK 233 1 Peptidyl-prolyl cis-trans isomerase-like 4 PPR3D_HUMAN O95685 32 1 Protein phosphatase 1 regulatory subunit 3D PR40A_HUMAN O75400 134 1 Pre-mRNA-processing factor 40 homolog A PRD15_HUMAN P57071 1270 1 PR domain zinc finger protein 15 PRD15_HUMAN P57071 1270 1 PR domain zinc finger protein 15 219 PRKDC_HUMAN P78527 GDPSDRMEVQEQ 3212 1 DNA-dependent protein EEDISSLIR kinase catalytic subunit PROF1_HUMAN P07737 20 1 Profilin-1 PROF1_HUMAN P07737 82 1 Profilin-1 PROF1_HUMAN P07737 82 1 Profilin-1 PROF1_HUMAN P07737 15 1 Profilin-1 PRP17_HUMAN O60508 56 1 Pre-mRNA-processing factor 17 220 PRP17_HUMAN O60508 VAKPSEEEQKELD 205 1 Pre-mRNA-processing factor EITAKR 17 PRP17_HUMAN O60508 191 1 Pre-mRNA-processing factor 17 PRP17_HUMAN O60508 205 1 Pre-mRNA-processing factor 17 PRP17_HUMAN O60508 205 1 Pre-mRNA-processing factor 17 PRP31_HUMAN Q8WWY3 387 1 U4/U6 small nuclear ribonucleoprotein Prp31 PRR12_HUMAN Q9ULL5 116 1 Proline-rich protein 12 PRR3_HUMAN P79522 32 1 Proline-rich protein 3 PRS10_HUMAN P62333 266 1 26S protease regulatory subunit S10B 221 PRS6A_HUMAN P17980 GIGEEVLK 28 1 26S protease regulatory subunit 6A PRS6A_HUMAN P17980 28 1 26S protease regulatory subunit 6A 222 PRS6A_HUMAN P17980 GIGEEVLKMSTEE 28 1 26S protease regulatory IIQR subunit 6A PRS6A_HUMAN P17980 319 1 26S protease regulatory subunit 6A 223 PRS6B_HUMAN P43686 GFDQNVNVK 298 1 26S protease regulatory subunit 6B 224 PRS8_HUMAN P62195 SIGSSRLEGGSGG 253 1 26S protease regulatory DSEVQR subunit 8 PSA5_HUMAN P28066 72 1 Proteasome subunit alpha type-5 PSA7L_HUMAN Q8TAA3 16 2 Proteasome subunit alpha type-7-like PSA7_HUMAN O14818 14 Proteasome subunit alpha type-7 PSB1_HUMAN P20618 48 1 Proteasome subunit beta type-1 225 PSB4_HUMAN P28070 SFMDPASALYR 30 1 Proteasome subunit beta type-4 PSB7_HUMAN Q99436 54 1 Proteasome subunit beta type-7 226 PSD12_HUMAN O00232 YSATVDQR 20 1 26S proteasome non-ATPase regulatory subunit 12 PSD4_HUMAN Q8NDX1 83 1 PH and SEC7 domain- containing protein 4 PSD4_HUMAN Q8NDX1 536 1 PH and SEC7 domain- containing protein 4 PSIP1_HUMAN O75475 31 1 PC4 and SFRS1-interacting protein PSIP1_HUMAN O75475 31 1 PC4 and SFRS1-interacting protein 227 PSIP1_HUMAN O75475 SVITQVLNK 434 1 PC4 and SFRS1-interacting protein PSME3_HUMAN P61289 78 1 Proteasome activator complex subunit 3 PTBP1_HUMAN P26599 3 1 Polypyrimidine tract-binding protein 1 PTBP1_HUMAN P26599 3 1 Polypyrimidine tract-binding protein 1 PTBP1_HUMAN P26599 173 1 Polypyrimidine tract-binding protein 1 PTBP1_HUMAN P26599 173 1 Polypyrimidine tract-binding protein 1 PTBP1_HUMAN P26599 173 1 Polypyrimidine tract-binding protein 1 PTBP1_HUMAN P26599 173 1 Polypyrimidine tract-binding protein 1 PTBP1_HUMAN P26599 140 2 Polypyrimidine tract-binding protein 1 PTCA_HUMAN Q14761 121 1 Protein tyrosine phosphatase receptor type C-associated protein PTCA_HUMAN Q14761 121 1 Protein tyrosine phosphatase receptor type C-associated protein PTCA_HUMAN Q14761 117 1 Protein tyrosine phosphatase receptor type C-associated protein PTMA_HUMAN P06454 4 1 Prothymosin alpha PTMA_HUMAN P06454 4 1 Prothymosin alpha PTMA_HUMAN P06454 8 1 Prothymosin alpha PTMA_HUMAN P06454 8 1 Prothymosin alpha 228 PTN3_HUMAN P26045 GVDQQLLDDFHR 472 1 Tyrosine-protein phosphatase non-receptor type 3 229 PUR2_HUMAN P22102 GGPNTGGMGAYC 226 1 Trifunctional purine PAPQVSNDLLLK biosynthetic protein adenosine-3 PUR2_HUMAN P22102 206 1 Trifunctional purine biosynthetic protein adenosine-3 PUR2_HUMAN P22102 444 1 Trifunctional purine biosynthetic protein adenosine-3 PUR6_HUMAN P22234 320 1 Multifunctional protein ADE2 PUR6_HUMAN P22234 27 1 Multifunctional protein ADE2 230 PUR9_HUMAN P31939 GIIAPGYEEEALTI 340 1 Bifunctional purine LSK biosynthesis protein PURH PUS7_HUMAN Q96PZ0 51 1 Pseudouridylate synthase 7 homolog PUS7_HUMAN Q96PZ0 23 1 Pseudouridylate synthase 7 homolog 231 PWP2A_HUMAN Q96N64 GQQSAPQADEPPL 56 1 PWWP domain-containing PPPPPPPGELAR protein 2A PYR1_HUMAN P27708 1139 1 CAD protein QKI_HUMAN Q96PU8 75 1 Protein quaking QN1_HUMAN Q5TB80 248 1 Protein QN1 homolog QSER1_HUMAN Q2KHR3 1322 1 Glutamine and serine-rich protein 1 232 QSK_HUMAN Q9Y2K2 GTLNLDSDEGEEP 384 1 Serine/threonine-protein SPEALVR kinase QSK R3HD1_HUMAN Q15032 500 1 R3H domain-containing protein 1 R3HD1_HUMAN Q15032 500 1 R3H domain-containing protein 1 RA1L3_HUMAN P0C7M2 158 3 Putative heterogeneous nuclear ribonucleoprotein A1-like protein 3 ROA1L_HUMAN Q32P51 158 Heterogeneous nuclear ribonucleoprotein A1-like protein ROA1_HUMAN P09651 158 Heterogeneous nuclear ribonucleoprotein A1 RA1L3_HUMAN P0C7M2 95 3 Putative heterogeneous nuclear ribonucleoprotein A1-like protein 3 ROA1L_HUMAN Q32P51 95 Heterogeneous nuclear ribonucleoprotein A1-like protein ROA1_HUMAN P09651 95 Heterogeneous nuclear ribonucleoprotein A1 RA1L3_HUMAN P0C7M2 70 2 Putative heterogeneous nuclear ribonucleoprotein A1-like protein 3 ROA1_HUMAN P09651 70 Heterogeneous nuclear ribonucleoprotein A1 RA1L3_HUMAN P0C7M2 158 2 Putative heterogeneous nuclear ribonucleoprotein A1-like protein 3 ROA1_HUMAN P09651 158 Heterogeneous nuclear ribonucleoprotein A1 RA1L3_HUMAN P0C7M2 70 2 Putative heterogeneous nuclear ribonucleoprotein A1-like protein 3 ROA1_HUMAN P09651 70 Heterogeneous nuclear ribonucleoprotein A1 233 RAD21_HUMAN O60216 SVDPVEPMPTMT 280 1 Double-strand-break repair DQTTLVPNEEEAF protein rad21 homolog ALEPIDITVK RAD21_HUMAN O60216 280 1 Double-strand-break repair protein rad21 homolog 234 RAD21_HUMAN O60216 SVDPVEPMPTMT 280 1 Double-strand-break repair DQTTLVPNEEEAF protein rad21 homolog ALEPIDITVKETK 235 RAD21_HUMAN O60216 VAQQFSLNQSR 129 1 Double-strand-break repair protein rad21 homolog RADIL_HUMAN Q96JH8 842 1 Ras-associating and dilute domain-containing protein RADIL_HUMAN Q96JH8 842 1 Ras-associating and dilute domain-containing protein RANG_HUMAN P43487 128 1 Ran-specific GTPase- activating protein RB3GP_HUMAN Q15042 253 1 Rab3 GTPase-activating protein catalytic subunit RBBP4_HUMAN Q09028 362 2 Histone-binding protein RBBP4 RBBP7_HUMAN Q16576 361 Histone-binding protein RBBP7 RBBP6_HUMAN Q7Z6E9 973 1 Retinoblastoma-binding protein 6 RBBP6_HUMAN Q7Z6E9 1679 1 Retinoblastoma-binding protein 6 RBBP6_HUMAN Q7Z6E9 1268 1 Retinoblastoma-binding protein 6 RBBP6_HUMAN Q7Z6E9 1268 1 Retinoblastoma-binding protein 6 236 RBBP7_HUMAN Q16576 SDKGEFGGFGSVT 99 1 Histone-binding protein GK RBBP7 RBBP7_HUMAN Q16576 94 1 Histone-binding protein RBBP7 RBBP8_HUMAN Q99708 743 1 Retinoblastoma-binding protein 8 RBM15_HUMAN Q96T37 751 1 Putative RNA-binding protein 15 237 RBM16_HUMAN Q9UPN6 GVEEEVFEQEAK 381 1 Putative RNA-binding protein 16 RBM16_HUMAN Q9UPN6 776 1 Putative RNA-binding protein 16 RBM25_HUMAN P49756 634 1 Probable RNA-binding protein 25 RBM26_HUMAN Q5T8P6 432 1 RNA-binding protein 26 238 RBM26_HUMAN Q5T8P6 GYNPEAPSITNTS 432 1 RNA-binding protein 26 RPMYR RBM26_HUMAN Q5T8P6 281 1 RNA-binding protein 26 RBM26_HUMAN Q5T8P6 281 1 RNA-binding protein 26 RBM27_HUMAN Q9P2N5 488 1 RNA-binding protein 27 RBM28_HUMAN Q9NW13 245 1 RNA-binding protein 28 RBM33_HUMAN Q96EV2 999 1 RNA-binding protein 33 239 RBM39_HUMAN Q14498 ASSASSFLDSDEL 332 1 RNA-binding protein 39 ER 240 RBM39_HUMAN Q14498 ASSASSFLDSDEL 332 1 RNA-binding protein 39 ERTGIDLGTTGR RBM8A_HUMAN Q9Y5S9 7 1 RNA-binding protein 8A RBM8A_HUMAN Q9Y5S9 7 1 RNA-binding protein 8A RBM8A_HUMAN Q9Y5S9 7 1 RNA-binding protein 8A RBM8A_HUMAN Q9Y5S9 7 1 RNA-binding protein 8A RBM8A_HUMAN Q9Y5S9 7 1 RNA-binding protein 8A 241 RBM8A_HUMAN Q9Y5S9 SVEQDGDEPGPQR 56 1 RNA-binding protein 8A RBM9_HUMAN O43251 103 1 RNA-binding protein 9 RBP2_HUMAN P49792 2491 1 E3 SUMO-protein ligase RanBP2 242 RBP2_HUMAN P49792 GGSAHGDDDDDG 1158 1 E3 SUMO-protein ligase PHFEPVVPLPDKI RanBP2 EVK 243 RBP2_HUMAN P49792 GTGGQSIYGDKFE 3132 1 E3 SUMO-protein ligase DENFDVK RanBP2 RBP2_HUMAN P49792 2861 1 E3 SUMO-protein ligase RanBP2 RBP2_HUMAN P49792 1158 1 E3 SUMO-protein ligase RanBP2 RBP2_HUMAN P49792 2307 7 E3 SUMO-protein ligase RanBP2 RGPD1_HUMAN Q68DN6 1316 RANBP2-like and GRIP domain-containing protein 1 RGPD3_HUMAN A6NKT7 1332 RANBP2-like and GRIP domain-containing protein 3 RGPD4_HUMAN Q7Z3J3 1332 RANBP2-like and GRIP domain-containing protein 4 RGPD5_HUMAN Q99666 1331 RANBP2-like and GRIP domain-containing protein 5 RGPD6_HUMAN Q53T03 1331 RANBP2-like and GRIP domain-containing protein 6 RGPD8_HUMAN O14715 321 RANBP2-like and GRIP domain-containing protein 8 (Fragment) RBP2_HUMAN P49792 2237 6 E3 SUMO-protein ligase RanBP2 RGPD3_HUMAN A6NKT7 1262 RANBP2-like and GRIP domain-containing protein 3 RGPD4_HUMAN Q7Z3J3 1262 RANBP2-like and GRIP domain-containing protein 4 RGPD5_HUMAN Q99666 1261 RANBP2-like and GRIP domain-containing protein 5 RGPD6_HUMAN Q53T03 1261 RANBP2-like and GRIP domain-containing protein 6 RGPD8_HUMAN O14715 251 RANBP2-like and GRIP domain-containing protein 8 (Fragment) RBP56_HUMAN Q92804 141 1 TATA-binding protein- associated factor 2N RBTN1_HUMAN P25800 9 1 Rhombotin-1 RBY1B_HUMAN A6NDE4 467 3 RNA-binding motif protein, Y chromosome, family 1 member B RBY1F_HUMAN Q15415 467 RNA-binding motif protein, Y chromosome, family 1 member F/J RBY1H_HUMAN Q15378 327 Putative RNA-binding motif protein, Y chromosome, family 1 member H 244 RB_HUMAN P06400 SIDSFETQR 347 1 Retinoblastoma-associated protein RCAN1_HUMAN P53805 4 1 Calcipressin-1 RCC2_HUMAN Q9P258 61 1 Protein RCC2 RCC2_HUMAN Q9P258 61 1 Protein RCC2 RCN2_HUMAN Q14257 204 1 Reticulocalbin-2 RCOR2_HUMAN Q8IZ40 392 1 REST corepressor 2 RCOR2_HUMAN Q8IZ40 392 1 REST corepressor 2 RCOR2_HUMAN Q8IZ40 392 1 REST corepressor 2 RCOR2_HUMAN Q8IZ40 392 1 REST corepressor 2 RD23B_HUMAN P54727 166 1 UV excision repair protein RAD23 homolog B 245 RED_HUMAN Q13123 GVNKDYEETELIS 109 1 Protein Red TTANYR 246 RED_HUMAN Q13123 YVPSTTK 325 2 Protein Red 247 RED_HUMAN Q13123 YVPSTTKTPR 325 1 Protein Red 248 REL_HUMAN Q04864 GYYEAEFGQER 87 1 C-Rel proto-oncogene protein RENT1_HUMAN Q92900 76 1 Regulator of nonsense transcripts 1 249 REPS1_HUMAN Q96D71 SFTSDPEQIGSNV 466 1 RalBP1-associated Eps TR domain-containing protein 1 250 REPS1_HUMAN Q96D71 SNIAPADPDTAIV 387 1 RalBP1-associated Eps HPVPIR domain-containing protein 1 251 REPS1_HUMAN Q96D71 GYSSSDSFTSDPE 460 1 RalBP1-associated Eps QIGSNVTR domain-containing protein 1 REQU_HUMAN Q92785 244 1 Zinc finger protein ubi-d4 252 REQU_HUMAN Q92785 GSSLEALLR 116 1 Zinc finger protein ubi-d4 REST_HUMAN Q13127 942 1 RE1-silencing transcription factor RFC1_HUMAN P35251 724 1 Replication factor C subunit 1 253 RFC1_HUMAN P35251 GMAGNEDR 724 1 Replication factor C subunit 1 254 RFC1_HUMAN P35251 GMAGNEDRGGIQ 724 1 Replication factor C subunit 1 ELIGLIK RFC1_HUMAN P35251 168 1 Replication factor C subunit 1 RFX7_HUMAN Q2KHR2 480 1 DNA-binding protein RFX7 RGAP1_HUMAN Q9H0H5 274 1 Rac GTPase-activating protein 1 RGAP1_HUMAN Q9H0H5 274 1 Rac GTPase-activating protein 1 RGPD1_HUMAN Q68DN6 1500 7 RANBP2-like and GRIP domain-containing protein 1 RGPD2_HUMAN P0C839 765 RANBP2-like and GRIP domain-containing protein 2 RGPD3_HUMAN A6NKT7 1516 RANBP2-like and GRIP domain-containing protein 3 RGPD4_HUMAN Q7Z3J3 1516 RANBP2-like and GRIP domain-containing protein 4 RGPD5_HUMAN Q99666 1515 RANBP2-like and GRIP domain-containing protein 5 RGPD6_HUMAN Q53T03 1515 RANBP2-like and GRIP domain-containing protein 6 RGPD8_HUMAN O14715 505 RANBP2-like and GRIP domain-containing protein 8 (Fragment) RGS10_HUMAN O43665 15 1 Regulator of G-protein signaling 10 RGS10_HUMAN O43665 13 1 Regulator of G-protein signaling 10 RHG04_HUMAN P98171 404 1 Rho GTPase-activating protein 4 RHG04_HUMAN P98171 404 1 Rho GTPase-activating protein 4 255 RHG25_HUMAN P42331 SFSSMTSDSDTTS 388 1 Rho GTPase-activating PTGQQPSDAFPED protein 25 SSKVPR RHG25_HUMAN P42331 398 1 Rho GTPase-activating protein 25 256 RHG30_HUMAN Q7Z6I6 GCLCPCSLGLGG 908 1 Rho GTPase-activating VGMR protein 30 RHG30_HUMAN Q7Z6I6 593 1 Rho GTPase-activating protein 30 257 RHG30_HUMAN Q7Z6I6 SIEAAEGEQEPEA 364 1 Rho GTPase-activating EALGGTNSEPGTPR protein 30 RHGBA_HUMAN Q6P4F7 257 1 Rho GTPase-activating protein 11A 258 RHOA_HUMAN P61586 SLENIPEKWTPEVK 91 2 Transforming protein RhoA 258 RHOC_HUMAN P08134 SLENIPEKWTPEVK 91 Rho-related GTP-binding protein RhoC RIF1_HUMAN Q5UIP0 1810 1 Telomere-associated protein RIF1 RIF1_HUMAN Q5UIP0 2001 1 Telomere-associated protein RIF1 RIMB1_HUMAN O95153 1808 1 Peripheral-type benzodiazepine receptor- associated protein 1 RIMB1_HUMAN O95153 45 1 Peripheral-type benzodiazepine receptor- associated protein 1 259 RING1_HUMAN Q06587 GTEIAVSPR 32 1 E3 ubiquitin-protein ligase RING1 RIOK1_HUMAN Q9BRS2 130 1 Serine/threonine-protein kinase RIO1 RIOK1_HUMAN Q9BRS2 130 1 Serine/threonine-protein kinase RIO1 RIPK1_HUMAN Q13546 559 1 Receptor-interacting serine/threonine-protein kinase 1 RIR2_HUMAN P31350 30 1 Ribonucleoside-diphosphate reductase subunit M2 RL17_HUMAN P18621 111 1 60S ribosomal protein L17 260 RL5_HUMAN P46777 GQPGAFTCYLDA 137 1 60S ribosomal protein L5 GLAR RL5_HUMAN P46777 169 1 60S ribosomal protein L5 RN168_HUMAN Q8IYW5 251 1 RING finger protein 168 261 RN213_HUMAN Q63HN8 GVREEDLAPFSLR 356 1 RING finger protein 213 RN219_HUMAN Q5W0B1 434 1 RING finger protein 219 RN220_HUMAN Q5VTB9 414 1 RING finger protein 220 RNF5_HUMAN Q99942 9 1 E3 ubiquitin-protein ligase RNF5 RNZ1_HUMAN Q9H777 280 1 Zinc phosphodiesterase ELAC protein 1 ROA0_HUMAN Q13151 63 1 Heterogeneous nuclear ribonucleoprotein A0 ROA0_HUMAN Q13151 74 1 Heterogeneous nuclear ribonucleoprotein A0 ROA0_HUMAN Q13151 63 1 Heterogeneous nuclear ribonucleoprotein A0 ROA0_HUMAN Q13151 63 1 Heterogeneous nuclear ribonucleoprotein A0 ROA2_HUMAN P22626 77 1 Heterogeneous nuclear ribonucleoproteins A2/B1 ROA2_HUMAN P22626 77 1 Heterogeneous nuclear ribonucleoproteins A2/B1 ROA2_HUMAN P22626 77 1 Heterogeneous nuclear ribonucleoproteins A2/B1 ROA2_HUMAN P22626 131 1 Heterogeneous nuclear ribonucleoproteins A2/B1 ROA3_HUMAN P51991 91 1 Heterogeneous nuclear ribonucleoprotein A3 262 ROA3_HUMAN P51991 SVKPGAHLTVKK 116 1 Heterogeneous nuclear ribonucleoprotein A3 ROA3_HUMAN P51991 179 1 Heterogeneous nuclear ribonucleoprotein A3 ROA3_HUMAN P51991 91 1 Heterogeneous nuclear ribonucleoprotein A3 ROA3_HUMAN P51991 116 1 Heterogeneous nuclear ribonucleoprotein A3 ROCK1_HUMAN Q13464 1114 1 Rho-associated protein kinase 1 RPAP3_HUMAN Q9H6T3 125 1 RNA polymerase II- associated protein 3 RPAP3_HUMAN Q9H6T3 452 1 RNA polymerase II- associated protein 3 RPAP3_HUMAN Q9H6T3 452 1 RNA polymerase II- associated protein 3 RPB9_HUMAN P36954 5 1 DNA-directed RNA polymerase II subunit RPB9 RPC4_HUMAN P05423 132 1 DNA-directed RNA polymerase III subunit RPC4 263 RPC5_HUMAN Q9NVU0 SFNGHPPQGCAST 544 1 DNA-directed RNA PVAR polymerase III subunit RPC5 RPGF6_HUMAN Q8TEU7 1283 1 Rap guanine nucleotide exchange factor 6 264 RPGF6_HUMAN Q8TEU7 SMSAALQDER 1283 1 Rap guanine nucleotide exchange factor 6 RREB1_HUMAN Q92766 1174 1 RAS-responsive element- binding protein 1 265 RRMJ3_HUMAN Q8IY81 STAGTTKQPSKEE 347 1 Putative rRNA EEEEEEEQLNQTL methyltransferase 3 AEMK RRP12_HUMAN Q5JTH9 1162 1 RRP12-like protein RRP12_HUMAN Q5JTH9 1162 1 RRP12-like protein RRP12_HUMAN Q5JTH9 1162 1 RRP12-like protein 266 RRP12_HUMAN Q5JTH9 GNKMEEEEGAKG 1162 1 RRP12-like protein EDEEMADPMEDV IIR RRP12_HUMAN Q5JTH9 557 1 RRP12-like protein RRP1B_HUMAN Q14684 276 1 Ribosomal RNA processing protein 1 homolog B RS20_HUMAN P60866 6 1 40S ribosomal protein S20 RS23_HUMAN P62266 89 1 40S ribosomal protein S23 RS23_HUMAN P62266 89 1 40S ribosomal protein S23 RS28_HUMAN P62857 55 1 40S ribosomal protein S28 RS3_HUMAN P23396 33 1 40S ribosomal protein S3 267 RSRC1_HUMAN Q96IZ7 SFVQQTFR 239 1 Arginine/serine-rich coiled- coil protein 1 RTF1_HUMAN Q92541 141 1 RNA polymerase-associated protein RTF1 homolog 268 RTF1_HUMAN Q92541 GYGEDLMGDEEDR 141 1 RNA polymerase-associated protein RTF1 homolog 269 RTF1_HUMAN Q92541 GYGEDLMGDEED 141 1 RNA polymerase-associated RAR protein RTF1 homolog RTN4_HUMAN Q9NQC3 85 1 Reticulon-4 RTN4_HUMAN Q9NQC3 906 1 Reticulon-4 270 RU1C_HUMAN P09234 TYLTHDSPSVRK 11 1 U1 small nuclear ribonucleoprotein C 271 RU1C_HUMAN P09234 TYLTHDSPSVR 11 1 U1 small nuclear ribonucleoprotein C 272 RU2A_HUMAN P09661 AIDFSDNEIR 46 1 U2 small nuclear ribonucleoprotein A′ 273 RUSD2_HUMAN Q8IZ73 STAPSSELGKDDL 442 1 RNA pseudouridylate EELAAAAQK synthase domain-containing protein 2 RUXF_HUMAN P62306 53 1 Small nuclear ribonucleoprotein F S11IP_HUMAN Q8N1F8 373 1 Serine/threonine kinase 11- interacting protein S12A2_HUMAN P55011 67 1 Solute carrier family 12 member 2 S2546_HUMAN Q96AG3 11 1 Solute carrier family 25 member 46 274 S30BP_HUMAN Q9UHR5 AYGEDDFSR 45 1 SAP30-binding protein SAFB1_HUMAN Q15424 147 1 Scaffold attachment factor B1 SAFB1_HUMAN Q15424 797 2 Scaffold attachment factor B1 SAFB2_HUMAN Q14151 821 Scaffold attachment factor B2 SAFB1_HUMAN Q15424 263 2 Scaffold attachment factor B SAFB2_HUMAN Q14151 262 Scaffold attachment factor B2 SAFB1_HUMAN Q15424 263 2 Scaffold attachment factor B1 SAFB2_HUMAN Q14151 262 Scaffold attachment factor B2 SAFB1_HUMAN Q15424 263 2 Scaffold attachment factor B1 SAFB2_HUMAN Q14151 262 Scaffold attachment factor B2 SAFB1_HUMAN Q15424 361 2 Scaffold attachment factor B1 SAFB2_HUMAN Q14151 360 Scaffold attachment factor B2 SAFB1_HUMAN Q15424 797 2 Scaffold attachment factor B1 SAFB2_HUMAN Q14151 821 Scaffold attachment factor B2 SAFB2_HUMAN Q14151 184 1 Scaffold attachment factor B2 SAFB2_HUMAN Q14151 154 1 Scaffold attachment factor B2 SAFB2_HUMAN Q14151 154 1 Scaffold attachment factor B2 SAHH2_HUMAN O43865 6 1 Putative adenosylhomocysteinase 2 275 SAHH2_HUMAN O43865 SYSSAASYTDSSD 74 1 Putative DEVSPR adenosylhomocysteinase 2 276 SAHH2_HUMAN O43865 SYSSAASYTDSSD 74 1 Putative DEVSPREK adenosylhomocysteinase 2 SAHH2_HUMAN O43865 6 1 Putative adenosylhomocysteinase 2 SAHH2_HUMAN O43865 6 1 Putative adenosylhomocysteinase 2 SAHH2_HUMAN O43865 6 1 Putative adenosylhomocysteinase 2 SAHH2_HUMAN O43865 84 1 Putative adenosylhomocysteinase 2 SAHH3_HUMAN Q96HN2 110 1 Putative adenosylhomocysteinase 3 SAM4B_HUMAN Q5PRF9 413 1 Sterile alpha motif domain- containing protein 4B SAPS1_HUMAN Q9UPN7 359 1 Serine/threonine-protein phosphatase 6 regulatory subunit 1 277 SAP_HUMAN P07602 VYCEVCEFLVK 313 1 Proactivator polypeptide 278 SAP_HUMAN P07602 VYCEVCEFLVKE 313 1 Proactivator polypeptide VTK SAP_HUMAN P07602 406 1 Proactivator polypeptide 279 SASH3_HUMAN O75995 YSLDSPGPEK 116 1 SAM and SH3 domain- containing protein 3 SASH3_HUMAN O75995 56 1 SAM and SH3 domain- containing protein 3 SATB1_HUMAN Q01826 255 1 DNA-binding protein SATB1 SATT_HUMAN P43007 13 1 Neutral amino acid transporter A SC16A_HUMAN O15027 838 1 Protein transport protein Sec16A SC16A_HUMAN O15027 342 1 Protein transport protein Sec16A SC24B_HUMAN O95487 296 1 Protein transport protein Sec24B SCAM3_HUMAN O14828 40 1 Secretory carrier-associated membrane protein 3 SCMH1_HUMAN Q96GD3 512 1 Polycomb protein SCMH1 SCO1_HUMAN O75880 189 1 Protein SCO1 homolog, mitochondrial SCO1_HUMAN O75880 189 1 Protein SCO1 homolog, mitochondrial SCOC_HUMAN Q9UIL1 88 1 Short coiled-coil protein SCOC_HUMAN Q9UIL1 88 1 Short coiled-coil protein SDCG1_HUMAN O60524 780 1 Serologically defined colon cancer antigen 1 SEC13_HUMAN P55735 15 1 Protein SEC13 homolog SEC20_HUMAN Q12981 33 1 Vesicle transport protein SEC20 SENP6_HUMAN Q9GZR1 50 1 Sentrin-specific protease 6 SEPT9_HUMAN Q9UHD8 283 1 Septin-9 SETD2_HUMAN Q9BYW2 648 1 Histone-lysine N- methyltransferase SETD2 SETD2_HUMAN Q9BYW2 1170 1 Histone-lysine N- methyltransferase SETD2 SETD2_HUMAN Q9BYW2 1170 1 Histone-lysine N- methyltransferase SETD2 280 SETX_HUMAN Q7Z333 SVSRPQLESLSGTK 1535 1 Probable helicase senataxin SF01_HUMAN Q15637 449 1 Splicing factor 1 SF3A1_HUMAN Q15459 504 1 Splicing factor 3 subunit 1 SF3A1_HUMAN Q15459 504 1 Splicing factor 3 subunit 1 SF3A1_HUMAN Q15459 33 1 Splicing factor 3 subunit 1 281 SF3B1_HUMAN O75533 STGYYDQEIYGGS 35 1 Splicing factor 3B subunit 1 DSR SF3B2_HUMAN Q13435 292 1 Splicing factor 3B subunit 2 282 SF3B2_HUMAN Q13435 GSETPQLFTVLPEK 754 1 Splicing factor 3B subunit 2 283 SF3B2_HUMAN Q13435 GSETPQLFTVLPE 754 1 Splicing factor 3B subunit 2 KR SF3B4_HUMAN Q15427 13 1 Splicing factor 3B subunit 4 SFPQ_HUMAN P23246 526 1 Splicing factor, proline- and glutamine-rich SFR14_HUMAN Q8IX01 733 1 Putative splicing factor, arginine/serine-rich 14 SFR14_HUMAN Q8IX01 902 1 Putative splicing factor, arginine/serine-rich 14 284 SFR14_HUMAN Q8IX01 GLPGEAAEDDLA 923 1 Putative splicing factor, GAPALSQASSGTC arginine/serine-rich 14 FPR 285 SFRIP_HUMAN Q99590 SFCSDQNESEVEP 408 1 SFRS2-interacting protein SVNADLK SFRS2_HUMAN Q01130 71 1 Splicing factor, arginine/serine-rich 2 SFRS2_HUMAN Q01130 71 1 Splicing factor, arginine/serine-rich 2 SFRS2_HUMAN Q01130 74 1 Splicing factor, arginine/serine-rich 2 SFRS2_HUMAN Q01130 74 1 Splicing factor, arginine/serine-rich 2 SFRS3_HUMAN P84103 5 1 Splicing factor, arginine/serine-rich 3 SFRS5_HUMAN Q13243 53 1 Splicing factor, arginine/serine-rich 5 SFRS6_HUMAN Q13247 168 1 Splicing factor, arginine/serine-rich 6 SGOL1_HUMAN Q5FBB7 207 1 Shugoshin-like 1 SH2D3_HUMAN Q8N5H7 376 1 SH2 domain-containing protein 3C SHOT1_HUMAN A0MZ66 130 1 Shootin-1 286 SIPA1_HUMAN Q96FS4 GGSPPGPGDLAEER 815 1 Signal-induced proliferation- associated protein 1 SIX4_HUMAN Q9UIU6 297 1 Homeobox protein SIX4 287 SKI_HUMAN P12755 AAAPADAPSGLE 528 1 Ski oncogene AELEHLR SKT_HUMAN Q5T5P2 610 1 Sickle tail protein homolog SLD5_HUMAN Q9BRT9 7 1 DNA replication complex GINS protein SLD5 SLK_HUMAN Q9H2G2 404 1 STE20-like serine/threonine- protein kinase SLMAP_HUMAN Q14BN4 465 1 Sarcolemmal membrane- associated protein SLU7_HUMAN O95391 8 1 Pre-mRNA-splicing factor SLU7 SLU7_HUMAN O95391 8 1 Pre-mRNA-splicing factor SLU7 SLU7_HUMAN O95391 8 1 Pre-mRNA-splicing factor SLU7 SLU7_HUMAN O95391 8 1 Pre-mRNA-splicing factor SLU7 SMC2_HUMAN O95347 1117 1 Structural maintenance of chromosomes protein 2 SMCA4_HUMAN P51532 1382 1 Probable global transcription activator SNF2L4 SMCE1_HUMAN Q969G3 265 1 SWI/SNF-related matrix- associated actin-dependent regulator of chromatin subfamily E member 1 SMHD1_HUMAN A6NHR9 6 1 Structural maintenance of chromosomes flexible hinge domain-containing protein 1 SMRC2_HUMAN Q8TAQ2 815 1 SWI/SNF complex subunit SMARCC2 SMRD2_HUMAN Q92925 136 1 SWI/SNF-related matrix- associated actin-dependent regulator of chromatin subfamily D member 2 SNPC4_HUMAN Q5SXM2 1169 1 snRNA-activating protein complex subunit 4 SNX12_HUMAN Q9UMY4 22 1 Sorting nexin-12 288 SNX29_HUMAN Q8TEQ0 GEVTVAEQKPGEI 183 1 Sorting nexin-29 AEELASSYER SNX2_HUMAN O60749 85 1 Sorting nexin-2 SNX3_HUMAN O60493 33 1 Sorting nexin-3 SNX6_HUMAN Q9UNH7 11 1 Sorting nexin-6 SNX6_HUMAN Q9UNH7 11 1 Sorting nexin-6 SOBP_HUMAN A7XYQ1 299 1 Sine oculis-binding protein homolog 289 SODC_HUMAN P00441 GVADVSIEDSVIS 94 1 Superoxide dismutase [Cu—Zn] LSGDHCIIGR 290 SODC_HUMAN P00441 SVISLSGDHCIIGR 103 1 Superoxide dismutase [Cu—Zn] SON_HUMAN P18583 1641 1 SON protein 291 SON_HUMAN P18583 SFLKFDSEPSAVA 154 1 SON protein LELPTR SON_HUMAN P18583 1719 1 SON protein SON_HUMAN P18583 1641 1 SON protein SON_HUMAN P18583 353 1 SON protein SP110_HUMAN Q9HB58 354 1 Sp110 nuclear body protein SP110_HUMAN Q9HB58 354 1 Sp110 nuclear body protein SP1_HUMAN P08047 200 1 Transcription factor Sp1 SP3_HUMAN Q02447 276 1 Transcription factor Sp3 292 SP3_HUMAN Q02447 SAGIQLHPGENAD 531 1 Transcription factor Sp3 SPADIR SPAS2_HUMAN Q86XZ4 146 1 Spermatogenesis-associated serine-rich protein 2 SPAST_HUMAN Q9UBP0 471 1 Spastin SPD2B_HUMAN A1X283 683 1 SH3 and PX domain- containing protein 2B SPEC1_HUMAN Q5M775 214 1 Sperm antigen with calponin homology and coiled-coil domains 1 SPEE_HUMAN P19623 7 1 Spermidine synthase SPF27_HUMAN O75934 15 1 Pre-mRNA-splicing factor SPF27 293 SPF30_HUMAN O75940 SFASTQPTHSWK 63 1 Survival of motor neuron- related-splicing factor 30 SPG20_HUMAN Q8N0X7 497 1 Spartin SPG20_HUMAN Q8N0X7 497 1 Spartin SPG20_HUMAN Q8N0X7 497 1 Spartin SPS2L_HUMAN Q9NUQ6 120 1 SPATS2-like protein 294 SPT6H_HUMAN Q7KZ85 SYIEVLDGSR 1048 1 Transcription elongation factor SPT6 SPTA2_HUMAN Q13813 1479 1 Spectrin alpha chain, brain SPTA2_HUMAN Q13813 501 1 Spectrin alpha chain, brain SPTN2_HUMAN O15020 1753 1 Spectrin beta chain, brain 2 295 SR140_HUMAN O15042 GAPLEDVDGIPID 705 1 U2-associated protein SR140 ATPIDDLDGVPIK SR140_HUMAN O15042 713 1 U2-associated protein SR140 296 SR140_HUMAN O15042 GVPIKSLDDDLDG 726 1 U2-associated protein SR140 VPLDATEDSK 297 SR140_HUMAN O15042 GVPIKSLDDDLDG 726 1 U2-associated protein SR140 VPLDATEDSKK 298 SR140_HUMAN O15042 GVPLDATEDSK 738 1 U2-associated protein SR140 299 SR140_HUMAN O15042 GVPLDATEDSKK 738 1 U2-associated protein SR140 300 SR140_HUMAN O15042 GVPLDATEDSKK 738 1 U2-associated protein SR140 NEPIFK 301 SRCAP_HUMAN Q6ZRS2 GFPAGEGEEAGRP 2276 1 Helicase SRCAP GAEDEEMSR 302 SRCAP_HUMAN Q6ZRS2 GFPAGEGEEAGRP 2276 1 Helicase SRCAP GAEDEEMSR SRC_HUMAN P12931 46 1 Proto-oncogene tyrosine- protein kinase Src 303 SRFB1_HUMAN Q8NEF9 SVVSLESQK 212 1 Serum response factor- binding protein 1 304 SRFB1_HUMAN Q8NEF9 SVVSLESQKTPAD 212 1 Serum response factor- PKLK binding protein 1 305 SRP68_HUMAN Q9UHB9 AHQTETSSSQVK 538 1 Signal recognition particle 68 kDa DNKPLVER protein 306 SRP68_HUMAN Q9UHB9 AHQTETSSSQVK 538 1 Signal recognition particle 68 kDa protein SRPK1_HUMAN Q96SB4 413 1 Serine/threonine-protein kinase SRPK1 SRRM2_HUMAN Q9UQ35 148 1 Serine/arginine repetitive matrix protein 2 307 SRRM2_HUMAN Q9UQ35 SNSLLGQSR 1150 1 Serine/arginine repetitive matrix protein 2 SRRM2_HUMAN Q9UQ35 148 1 Serine/arginine repetitive matrix protein 2 SSA27_HUMAN O60232 82 1 Sjoegren syndrome/scleroderma autoantigen 1 SSBP3_HUMAN Q9BWW4 287 1 Single-stranded DNA- binding protein 3 SSF1_HUMAN Q9NQ55 246 1 Suppressor of SWI4 1 homolog SSFA2_HUMAN P28290 628 1 Sperm-specific antigen 2 SSH2_HUMAN Q76I76 964 1 Protein phosphatase Slingshot homolog 2 SSRP1_HUMAN Q08945 174 1 FACT complex subunit SSRP1 STAP1_HUMAN Q9ULZ2 171 1 Signal-transducing adaptor protein 1 308 STAP1_HUMAN Q9ULZ2 VLNPMPACFYTV 171 1 Signal-transducing adaptor SR protein 1 STK10_HUMAN O94804 333 1 Serine/threonine-protein kinase 10 STK24_HUMAN Q9Y6E0 326 1 Serine/threonine-protein kinase 24 STK24_HUMAN Q9Y6E0 326 1 Serine/threonine-protein kinase 24 STK39_HUMAN Q9UEW8 436 1 STE20/SPS1-related proline- alanine-rich protein kinase 309 STK4_HUMAN Q13043 GANTMIEHDDTL 350 1 Serine/threonine-protein PSQLGTMVINAED kinase 4 EEEEGTMK 310 STK4_HUMAN Q13043 GANTMIEHDDTL 350 1 Serine/threonine-protein PSQLGTMVINAED kinase 4 EEEEGTMKR 311 STK4_HUMAN Q13043 GANTMIEHDDTL 350 1 Serine/threonine-protein PSQLGTMVINAED kinase 4 EEEEGTMKRR STRN_HUMAN O43815 36 1 Striatin 312 STRN_HUMAN O43815 SLTYDIANNK 437 1 Striatin 313 STRN_HUMAN O43815 SLTYDIANNKDALR 437 1 Striatin 314 STRN_HUMAN O43815 SLTYDIANNKDAL 437 1 Striatin RK STX10_HUMAN O60499 197 1 Syntaxin-10 STX10_HUMAN O60499 139 1 Syntaxin-10 315 STX12_HUMAN Q86Y82 SIEANVESSEVHV 218 1 Syntaxin-12 ER STX17_HUMAN P56962 202 1 Syntaxin-17 STX17_HUMAN P56962 202 1 Syntaxin-17 316 STX7_HUMAN O15400 SIEANVENAEVHV 205 1 Syntaxin-7 QQANQQLSR 317 SUGT1_HUMAN Q9Y2Z0 ALIDEDPQAALEE 21 1 Suppressor of G2 allele of LTK SKP1 homolog SYAP1_HUMAN Q96A49 282 1 Synapse-associated protein 1 SYEP_HUMAN P07814 930 1 Bifunctional aminoacyl- tRNA synthetase 318 SYF2_HUMAN O95926 SAEEGSLAAAAEL 13 1 Pre-mRNA-splicing factor AAQK SYF2 319 SYF2_HUMAN O95926 SAEEGSLAAAAEL 13 1 Pre-mRNA-splicing factor AAQKR SYF2 SYG_HUMAN P41250 57 1 Glycyl-tRNA synthetase SYMPK_HUMAN Q92797 29 1 Symplekin SYNC_HUMAN O43776 410 1 Asparaginyl-tRNA synthetase, cytoplasmic SYNE1_HUMAN Q8NF91 8280 1 Nesprin-1 SYNE2_HUMAN Q8WXH0 4216 1 Nesprin-2 320 SYWC_HUMAN P23381 FVDPWTVQTSSAK 84 1 Tryptophanyl-tRNA synthetase, cytoplasmic T106B_HUMAN Q9NUM4 20 1 Transmembrane protein 106B T106B_HUMAN Q9NUM4 20 1 Transmembrane protein 106B T106C_HUMAN Q9BVX2 24 1 Transmembrane protein 106C T2EA_HUMAN P29083 304 1 General transcription factor IIE subunit 1 321 T2EA_HUMAN P29083 AFQEREEGHAGP 304 1 General transcription factor DDNEEVMR IIE subunit 1 T2FA_HUMAN P35269 273 1 General transcription factor IIF subunit 1 T2FA_HUMAN P35269 273 1 General transcription factor IIF subunit 1 TACC1_HUMAN O75410 324 1 Transforming acidic coiled- coil-containing protein 1 322 TACC1_HUMAN O75410 GHATDEEKLASTS 501 1 Transforming acidic coiled- CGQK coil-containing protein 1 323 TACC1_HUMAN O75410 GHATDEEK 501 1 Transforming acidic coiled- coil-containing protein 1 TACC2_HUMAN O95359 372 1 Transforming acidic coiled- coil-containing protein 2 TACC3_HUMAN Q9Y6A5 287 1 Transforming acidic coiled- coil-containing protein 3 TACC3_HUMAN Q9Y6A5 22 1 Transforming acidic coiled- coil-containing protein 3 TAD1L_HUMAN Q96BN2 79 1 Transcriptional adapter 1- like protein 324 TAF11_HUMAN Q15544 GIPEETDGDADVD 35 1 Transcription initiation factor LK TFIID subunit 11 TAF7_HUMAN Q15545 101 1 Transcription initiation factor TFIID subunit 7 TBA1A_HUMAN Q71U36 34 5 Tubulin alpha-1A chain TBA1B_HUMAN P68363 34 Tubulin alpha-1B chain TBA1C_HUMAN Q9BQE3 34 Tubulin alpha-1C chain TBA3C_HUMAN Q13748 34 Tubulin alpha-3C/D chain TBA3E_HUMAN Q6PEY2 34 Tubulin alpha-3E chain TBA1A_HUMAN Q71U36 34 5 Tubulin alpha-1A chain TBA1B_HUMAN P68363 34 Tubulin alpha-1B chain TBA1C_HUMAN Q9BQE3 34 Tubulin alpha-1C chain TBA3C_HUMAN Q13748 34 Tubulin alpha-3C/D chain TBA3E_HUMAN Q6PEY2 34 Tubulin alpha-3E chain TBA1A_HUMAN Q71U36 34 5 Tubulin alpha-1A chain TBA1B_HUMAN P68363 34 Tubulin alpha-1B chain TBA1C_HUMAN Q9BQE3 34 Tubulin alpha-1C chain TBA3C_HUMAN Q13748 34 Tubulin alpha-3C/D chain TBA3E_HUMAN Q6PEY2 34 Tubulin alpha-3E chain TBA1A_HUMAN Q71U36 48 5 Tubulin alpha-1A chain TBA1B_HUMAN P68363 48 Tubulin alpha-1B chain TBA1C_HUMAN Q9BQE3 48 Tubulin alpha-1C chain TBA3C_HUMAN Q13748 48 Tubulin alpha-3C/D chain TBA3E_HUMAN Q6PEY2 48 Tubulin alpha-3E chain TBA1A_HUMAN Q71U36 34 6 Tubulin alpha-1A chain TBA1B_HUMAN P68363 34 Tubulin alpha-1B chain TBA1C_HUMAN Q9BQE3 34 Tubulin alpha-1C chain TBA3C_HUMAN Q13748 34 Tubulin alpha-3C/D chain TBA3E_HUMAN Q6PEY2 34 Tubulin alpha-3E chain TBA4A_HUMAN P68366 34 Tubulin alpha-4A chain TBA1A_HUMAN Q71U36 200 7 Tubulin alpha-1A chain TBA1B_HUMAN P68363 200 Tubulin alpha-1B chain TBA1C_HUMAN Q9BQE3 200 Tubulin alpha-1C chain TBA3C_HUMAN Q13748 200 Tubulin alpha-3C/D chain TBA3E_HUMAN Q6PEY2 200 Tubulin alpha-3E chain TBA4A_HUMAN P68366 200 Tubulin alpha-4A chain TBA8_HUMAN Q9NY65 200 Tubulin alpha-8 chain TBA1A_HUMAN Q71U36 246 7 Tubulin alpha-1A chain TBA1B_HUMAN P68363 246 Tubulin alpha-1B chain TBA1C_HUMAN Q9BQE3 246 Tubulin alpha-1C chain TBA3C_HUMAN Q13748 246 Tubulin alpha-3C/D chain TBA3E_HUMAN Q6PEY2 246 Tubulin alpha-3E chain TBA4A_HUMAN P68366 246 Tubulin alpha-4A chain TBA8_HUMAN Q9NY65 246 Tubulin alpha-8 chain TBB2A_HUMAN Q13885 115 5 Tubulin beta-2A chain TBB2B_HUMAN Q9BVA1 115 Tubulin beta-2B chain TBB2C_HUMAN P68371 115 Tubulin beta-2C chain TBB3_HUMAN Q13509 115 Tubulin beta-3 chain TBB5_HUMAN P07437 115 Tubulin beta chain TBB2A_HUMAN Q13885 115 5 Tubulin beta-2A chain TBB2B_HUMAN Q9BVA1 115 Tubulin beta-2B chain TBB2C_HUMAN P68371 115 Tubulin beta-2C chain TBB3_HUMAN Q13509 115 Tubulin beta-3 chain TBB5_HUMAN P07437 115 Tubulin beta chain TBB2C_HUMAN P68371 115 2 Tubulin beta-2C chain TBB5_HUMAN P07437 115 Tubulin beta chain TBCC_HUMAN Q15814 154 1 Tubulin-specific chaperone C TBCD4_HUMAN O60343 273 1 TBC1 domain family member 4 TBCD4_HUMAN O60343 276 1 TBC1 domain family member 4 TBL1R_HUMAN Q9BZK7 153 1 F-box-like/WD repeat- containing protein TBL1XR1 325 TBL1R_HUMAN Q9BZK7 AVMPDVVQTR 86 2 F-box-like/WD repeat- containing protein TBL1XR1 325 TBL1X_HUMAN O60907 AVMPDVVQTR 86 F-box-like/WD repeat- containing protein TBL1X TBL1R_HUMAN Q9BZK7 153 2 F-box-like/WD repeat- containing protein TBL1XR1 TBL1Y_HUMAN Q9BQ87 163 F-box-like/WD repeat- containing protein TBL1Y TBL1X_HUMAN O60907 165 1 F-box-like/WD repeat- containing protein TBL1X TCEA1_HUMAN P23193 125 1 Transcription elongation factor A protein 1 TCF20_HUMAN Q9UGU0 1220 1 Transcription factor 20 TCF20_HUMAN Q9UGU0 1220 1 Transcription factor 20 TCF20_HUMAN Q9UGU0 1220 1 Transcription factor 20 TCOF_HUMAN Q13428 1243 1 Treacle protein 326 TCOF_HUMAN Q13428 GKQEAKPQQAAG 1243 1 Treacle protein MLSPK TCOF_HUMAN Q13428 1102 1 Treacle protein TCPD_HUMAN P50991 457 1 T-complex protein 1 subunit delta TCPD_HUMAN P50991 269 2 T-complex protein 1 subunit delta TCPD_HUMAN P50991 269 2 T-complex protein 1 subunit delta TCPE_HUMAN P48643 66 1 T-complex protein 1 subunit epsilon TCPE_HUMAN P48643 154 1 T-complex protein 1 subunit epsilon TCPZ_HUMAN P40227 405 1 T-complex protein 1 subunit zeta TCTP_HUMAN P13693 26 1 Translationally-controlled tumor protein TDRD6_HUMAN O60522 1919 1 Tudor domain-containing protein 6 TEX2_HUMAN Q8IWB9 357 1 Testis-expressed sequence 2 protein 327 TEX2_HUMAN Q8IWB9 GLSVSQAPAILPV 97 1 Testis-expressed sequence 2 SK protein TF2B_HUMAN Q00403 208 1 Transcription initiation factor IIB TF2B_HUMAN Q00403 208 1 Transcription initiation factor IIB TF2L1_HUMAN Q9NZI6 23 3 Transcription factor CP2-like protein 1 TFCP2_HUMAN Q12800 43 Alpha-globin transcription factor CP2 UBIP1_HUMAN Q9NZI7 40 Upstream-binding protein 1 328 TF3A_HUMAN Q92664 AFIAAGESSAPTPP 19 1 Transcription factor IIIA RPALPR TF65_HUMAN Q04206 98 1 Transcription factor p65 TGS1_HUMAN Q96RS0 344 1 Trimethylguanosine synthase homolog TGS1_HUMAN Q96RS0 344 1 Trimethylguanosine synthase homolog TGS1_HUMAN Q96RS0 338 1 Trimethylguanosine synthase homolog THOC4_HUMAN Q86V81 94 1 THO complex subunit 4 THOC5_HUMAN Q13769 18 1 THO complex subunit 5 homolog THOP1_HUMAN P52888 14 1 Thimet oligopeptidase TIF1A_HUMAN O15164 785 1 Transcription intermediary factor 1-alpha 329 TIF1B_HUMAN Q13263 ANQCCTSCEDNA 149 1 Transcription intermediary PATSYCVECSEPL factor 1-beta CETCVEAHQR TIF1B_HUMAN Q13263 106 1 Transcription intermediary factor 1-beta 330 TIF1B_HUMAN Q13263 STFSLDQPGGTLD 727 1 Transcription intermediary LTLIR factor 1-beta TIF1B_HUMAN Q13263 686 1 Transcription intermediary factor 1-beta TIF1B_HUMAN Q13263 689 1 Transcription intermediary factor 1-beta 331 TIM_HUMAN Q9UNS1 SVVPFDAASEVPV 580 1 Protein timeless homolog EEQR TINF2_HUMAN Q9BSI4 208 1 TERF1-interacting nuclear factor 2 332 TINF2_HUMAN Q9BSI4 SVNLAEPMEQNP 208 1 TERF1-interacting nuclear PQQQR factor 2 TLK2_HUMAN Q86UE8 133 1 Serine/threonine-protein kinase tousled-like 2 TM168_HUMAN Q9H0V1 427 1 Transmembrane protein 168 TM1L2_HUMAN Q6ZVM7 158 1 TOM1-like protein 2 TMUB1_HUMAN Q9BVT8 61 1 Transmembrane and ubiquitin-like domain- containing protein 1 333 TMUB1_HUMAN Q9BVT8 SMRGEAPGAETPS 61 1 Transmembrane and LR ubiquitin-like domain- containing protein 1 TNIP2_HUMAN Q8NFZ5 195 1 TNFAIP3-interacting protein 2 TNR6A_HUMAN Q8NDV7 1543 1 Trinucleotide repeat- containing gene 6A protein TNR6A_HUMAN Q8NDV7 1543 1 Trinucleotide repeat- containing gene 6A protein 334 TOE1_HUMAN Q96GM8 SIKPEETEQEVAA 374 1 Target of EGR1 protein 1 DETR TOE1_HUMAN Q96GM8 8 1 Target of EGR1 protein 1 335 TOIP1_HUMAN Q5JTV8 SILKSELGNQSPST 305 1 Torsin-1A-interacting protein 1 SSR TOIP1_HUMAN Q5JTV8 227 1 Torsin-1A-interacting protein 1 TOIP1_HUMAN Q5JTV8 227 1 Torsin-1A-interacting protein 1 TOLIP_HUMAN Q9H0E2 37 1 Toll-interacting protein TOM1_HUMAN O60784 394 1 Target of Myb protein 1 TOM1_HUMAN O60784 185 1 Target of Myb protein 1 TOM1_HUMAN O60784 180 1 Target of Myb protein 1 TOM1_HUMAN O60784 158 1 Target of Myb protein 1 336 TOM1_HUMAN O60784 MLSPIHTPQR 158 1 Target of Myb protein 1 TOP2B_HUMAN Q02880 1471 1 DNA topoisomerase 2-beta TP53B_HUMAN Q12888 212 1 Tumor suppressor p53- binding protein 1 337 TP53B_HUMAN Q12888 GCSTPSREEGGCS 318 1 Tumor suppressor p53- LASTPATTLHLLQ binding protein 1 LSGQR TP53B_HUMAN Q12888 1479 1 Tumor suppressor p53- binding protein 1 TP53B_HUMAN Q12888 318 1 Tumor suppressor p53- binding protein 1 338 TP53B_HUMAN Q12888 SSQPSLPLVR 830 1 Tumor suppressor p53- binding protein 1 TPD54_HUMAN O43399 3 1 Tumor protein D54 339 TPRGL_HUMAN Q5T0D9 SAGTSPTAVLAA 10 1 Tumor protein p63-regulated GEEVGAGGGPGG gene 1-like protein GRPGAGTPLR 340 TPRGL_HUMAN Q5T0D9 SAGTSPTAVLAA 10 1 Tumor protein p63-regulated GEEVGAGGGPGG gene 1-like protein GRPGAGTPLRQTL WPLSIHDPTR TPR_HUMAN P12270 1838 1 Nucleoprotein TPR TPR_HUMAN P12270 2148 1 Nucleoprotein TPR 341 TR150_HUMAN Q9Y2W1 SFDEDLARPSGLL 575 1 Thyroid hormone receptor- AQER associated protein 3 TRBP2_HUMAN Q15633 235 1 TAR RNA-binding protein 2 342 TREF1_HUMAN Q96PN7 GSNVTVTPGPGE 761 1 Transcriptional-regulating QTVDVEPR factor 1 TRI33_HUMAN Q9UPN9 830 1 E3 ubiquitin-protein ligase TRIM33 TRI33_HUMAN Q9UPN9 830 1 E3 ubiquitin-protein ligase TRIM33 TRI33_HUMAN Q9UPN9 830 1 E3 ubiquitin-protein ligase TRIM33 TRIP4_HUMAN Q15650 123 1 Activating signal cointegrator 1 TRIP4_HUMAN Q15650 289 1 Activating signal cointegrator 1 TRM1L_HUMAN Q7Z2T5 45 1 TRM1-like protein TRS85_HUMAN Q9Y2L5 854 1 Protein TRS85 homolog TSC1_HUMAN Q92574 639 1 Hamartin 343 TSC1_HUMAN Q92574 GVPSTSPMEVLDR 639 1 Hamartin LIQQGADAHSK 344 TSC1_HUMAN Q92574 GVPSTSPMEVLDR 639 1 Hamartin TSR1_HUMAN Q2NL82 333 1 Pre-rRNA-processing protein TSR1 homolog TSR1_HUMAN Q2NL82 333 1 Pre-rRNA-processing protein TSR1 homolog 345 TSR1_HUMAN Q2NL82 AVDDMEEGLK 333 1 Pre-rRNA-processing protein TSR1 homolog TSR1_HUMAN Q2NL82 333 1 Pre-rRNA-processing protein TSR1 homolog 346 TSR1_HUMAN Q2NL82 AVDDMEEGLKVL 333 1 Pre-rRNA-processing protein MK TSR1 homolog TTC1_HUMAN Q99614 66 1 Tetratricopeptide repeat protein 1 TTC4_HUMAN O95801 255 1 Tetratricopeptide repeat protein 4 347 TTF2_HUMAN Q9UNY4 STGRPLVILPQR 827 1 Transcription termination factor 2 348 TTF2_HUMAN Q9UNY4 STGRPLVILPQRK 827 1 Transcription termination factor 2 TYB10_HUMAN P63313 7 1 Thymosin beta-10 TYSY_HUMAN P04818 120 1 Thymidylate synthase TYY1_HUMAN P25490 120 1 Transcriptional repressor protein YY1 U119A_HUMAN Q13432 45 1 Protein unc-119 homolog A U119B_HUMAN A6NIH7 52 1 Protein unc-119 homolog B U2AF2_HUMAN P26368 129 1 Splicing factor U2AF 65 kDa subunit 349 U2AF2_HUMAN P26368 GLAVTPTPVPVV 129 1 Splicing factor U2AF 65 kDa GSQMTR subunit 350 UAP1L_HUMAN Q3KQV9 GVPQVVEYSEISP 300 1 UDP-N-acetylhexosamine ETAQLR pyrophosphorylase-like protein 1 UAP56_HUMAN Q13838 26 1 Spliceosome RNA helicase BAT1 351 UBA1_HUMAN P22314 ALECLPEDKEVLT 428 1 Ubiquitin-like modifier- EDK activating enzyme 1 UBA3_HUMAN Q8TBC4 26 1 NEDD8-activating enzyme E1 catalytic subunit UBA3_HUMAN Q8TBC4 26 1 NEDD8-activating enzyme E1 catalytic subunit UBAP2_HUMAN Q5T6F2 855 1 Ubiquitin-associated protein 2 UBAP2_HUMAN Q5T6F2 202 1 Ubiquitin-associated protein 2 UBAP2_HUMAN Q5T6F2 263 1 Ubiquitin-associated protein 2 UBE2O_HUMAN Q9C0C9 438 1 Ubiquitin-conjugating enzyme E2 O 352 UBE2O_HUMAN Q9C0C9 GSASPVEMQDEG 438 1 Ubiquitin-conjugating AEEPHEAGEQLPP enzyme E2 O FLLK 353 UBE2O_HUMAN Q9C0C9 GSASPVEMQDEG 438 1 Ubiquitin-conjugating AEEPHEAGEQLPP enzyme E2 O FLLKEGR 354 UBE2O_HUMAN Q9C0C9 GSASPVEMQDEG 438 1 Ubiquitin-conjugating AEEPHEAGEQLPP enzyme E2 O FLLKEGRDDR UBE2O_HUMAN Q9C0C9 1226 1 Ubiquitin-conjugating enzyme E2 O UBFD1_HUMAN O14562 233 1 Ubiquitin domain-containing protein UBFD1 355 UBN1_HUMAN Q9NPG3 SFIDNSEAYDELV 137 1 Ubinuclein PASLTTK UBP10_HUMAN Q14694 126 1 Ubiquitin carboxyl-terminal hydrolase 10 UBP10_HUMAN Q14694 139 1 Ubiquitin carboxyl-terminal hydrolase 10 UBP10_HUMAN Q14694 218 1 Ubiquitin carboxyl-terminal hydrolase 10 UBP14_HUMAN P54578 77 1 Ubiquitin carboxyl-terminal hydrolase 14 UBP14_HUMAN P54578 228 1 Ubiquitin carboxyl-terminal hydrolase 14 356 UBP19_HUMAN O94966 GRPDEVVAEEAW 620 1 Ubiquitin carboxyl-terminal QR hydrolase 19 UBP2L_HUMAN Q14157 412 1 Ubiquitin-associated protein 2-like UBP2L_HUMAN Q14157 299 1 Ubiquitin-associated protein 2-like 357 UBP2L_HUMAN Q14157 GSLASNPYSGDLTK 851 1 Ubiquitin-associated protein 2-like UBP34_HUMAN Q70CQ2 3367 1 Ubiquitin carboxyl-terminal hydrolase 34 UBP34_HUMAN Q70CQ2 3367 1 Ubiquitin carboxyl-terminal hydrolase 34 UBP36_HUMAN Q9P275 577 1 Ubiquitin carboxyl-terminal hydrolase 36 UBP42_HUMAN Q9H9J4 765 1 Ubiquitin carboxyl-terminal hydrolase 42 UBP5_HUMAN P45974 768 1 Ubiquitin carboxyl-terminal hydrolase 5 UBP5_HUMAN P45974 768 1 Ubiquitin carboxyl-terminal hydrolase 5 UBP5_HUMAN P45974 783 1 Ubiquitin carboxyl-terminal hydrolase 5 UBP5_HUMAN P45974 135 1 Ubiquitin carboxyl-terminal hydrolase 5 UBP5_HUMAN P45974 783 1 Ubiquitin carboxyl-terminal hydrolase 5 UBP7_HUMAN Q93009 51 1 Ubiquitin carboxyl-terminal hydrolase 7 358 UBP7_HUMAN Q93009 GHNTAEEDMEDD 51 1 Ubiquitin carboxyl-terminal TSWR hydrolase 7 UBQL1_HUMAN Q9UMX0 16 1 Ubiquilin-1 359 UBR4_HUMAN Q5T4S7 SVAGEHSVSGR 2904 1 E3 ubiquitin-protein ligase UBR4 360 UBXN7_HUMAN O94888 GFRDFQTETIR 110 1 UBX domain-containing protein 7 361 UBXN7_HUMAN O94888 GFRDFQTETIRQE 110 1 UBX domain-containing QELR protein 7 UBXN7_HUMAN O94888 401 1 UBX domain-containing protein 7 UGPA_HUMAN Q16851 16 1 UTP--glucose-1-phosphate uridylyltransferase UH1BL_HUMAN A0JNW5 1174 1 UHRF1-binding protein 1- like 362 UHRF1_HUMAN Q96T88 SRPADEDMWDET 119 1 E3 ubiquitin-protein ligase ELGLYK UHRF1 363 UHRF1_HUMAN Q96T88 SRPADEDMWDET 119 1 E3 ubiquitin-protein ligase ELGLYKVNEYVD UHRF1 AR 364 URP2_HUMAN Q86UX7 SLTTIPELK 345 1 Fermitin family homolog 3 365 URP2_HUMAN Q86UX7 SLTTIPELKDHLR 345 1 Fermitin family homolog 3 USE1_HUMAN Q9NZ43 130 1 Vesicle transport protein USE1 USF2_HUMAN Q15853 121 1 Upstream stimulatory factor 2 USO1_HUMAN O60763 758 1 General vesicular transport factor p115 UTRO_HUMAN P46939 262 1 Utrophin VAMP2_HUMAN P63027 69 2 Vesicle-associated membrane protein 2 VAMP3_HUMAN Q15836 52 Vesicle-associated membrane protein 3 VATD_HUMAN Q9Y5K8 118 1 V-type proton ATPase subunit D 366 VIME_HUMAN P08670 AINTEFK 91 1 Vimentin 367 VIME_HUMAN P08670 AINTEFKNTR 91 1 Vimentin 368 VIME_HUMAN P08670 ALKGTNESLER 332 1 Vimentin 369 VIME_HUMAN P08670 FSLADAINTEFK 86 1 Vimentin 370 VIME_HUMAN P08670 FSLADAINTEFKN 86 1 Vimentin TR VIME_HUMAN P08670 83 1 Vimentin VIME_HUMAN P08670 430 1 Vimentin 371 VIME_HUMAN P08670 VDVSKPDLTAALR 258 1 Vimentin 372 VIME_HUMAN P08670 VDVSKPDLTAAL 258 1 Vimentin RDVR 373 VIME_HUMAN P08670 VSKPDLTAALR 260 1 Vimentin 374 VIME_HUMAN P08670 VSKPDLTAALRD 260 1 Vimentin VR 375 VP13D_HUMAN Q5THJ4 SVGTYLPGASR 2611 1 Vacuolar protein sorting- associated protein 13D 376 VPS4A_HUMAN Q9UN37 SLCGSRNENESEA 231 1 Vacuolar protein sorting- AR associating protein 4A 377 VPS4A_HUMAN Q9UN37 SLCGSRNENESEA 231 1 Vacuolar protein sorting- ARR associating protein 4A VRK1_HUMAN Q99986 232 1 Serine/threonine-protein kinase VRK1 WAPL_HUMAN Q7Z5K2 155 1 Wings apart-like protein homolog WASF1_HUMAN Q92558 248 1 Wiskott-Aldrich syndrome protein family member 1 WASF2_HUMAN Q9Y6W5 243 1 Wiskott-Aldrich syndrome protein family member 2 WASF2_HUMAN Q9Y6W5 412 1 Wiskott-Aldrich syndrome protein family member 2 WASH1_HUMAN A8K0Z3 299 1 WAS protein family homolog 1 WDR33_HUMAN Q9C0J8 1184 1 WD repeat-containing protein 33 WDR44_HUMAN Q5JSH3 84 1 WD repeat-containing protein 44 WDR55_HUMAN Q9H6Y2 21 1 WD repeat-containing protein 55 WDR62_HUMAN O43379 1302 1 WD repeat-containing protein 62 378 WDR92_HUMAN Q96MX6 GIGGLGIGEGAPEI 119 1 WD repeat-containing VTGSR protein 92 WFS1_HUMAN O76024 212 1 Wolframin WFS1_HUMAN O76024 76 1 Wolframin WIPF1_HUMAN O43516 182 1 WAS/WASL-interacting protein family member 1 WNK1_HUMAN Q9H4A3 1070 1 Serine/threonine-protein kinase WNK1 WNK1_HUMAN Q9H4A3 1070 1 Serine/threonine-protein kinase WNK1 WNK1_HUMAN Q9H4A3 1070 1 Serine/threonine-protein kinase WNK1 WNK1_HUMAN Q9H4A3 2026 1 Serine/threonine-protein kinase WNK1 WNK1_HUMAN Q9H4A3 653 1 Serine/threonine-protein kinase WNK1 WNK1_HUMAN Q9H4A3 1070 1 Serine/threonine-protein kinase WNK1 WRIP1_HUMAN Q96S55 193 1 ATPase WRNIP1 WWC2_HUMAN Q6AWC2 856 1 Protein WWC2 XPA_HUMAN P23025 6 1 DNA repair protein complementing XP-A cells YAP1_HUMAN P46937 112 1 65 kDa Yes-associated protein YBOX1_HUMAN P67809 25 1 Nuclease-sensitive element- binding protein 1 YBOX1_HUMAN P67809 25 1 Nuclease-sensitive element- binding protein 1 YBOX1_HUMAN P67809 113 1 Nuclease-sensitive element- binding protein 1 YIPF3_HUMAN Q9GZM5 69 1 Protein YIPF3 YJ005_HUMAN Q6ZSR9 118 1 Uncharacterized protein FLJ45252 YJ005_HUMAN Q6ZSR9 124 1 Uncharacterized protein FLJ45252 YM017_HUMAN A8MX80 224 1 Putative UPF0607 protein ENSP00000383144 379 YTDC2_HUMAN Q9H6S0 GIPNDSSDSEMEDK 325 1 YTH domain-containing protein 2 YTHD1_HUMAN Q9BYJ9 165 1 YTH domain family protein 1 YTHD1_HUMAN Q9BYJ9 165 1 YTH domain family protein 1 YTHD1_HUMAN Q9BYJ9 165 1 YTH domain family protein 1 380 YTHD2_HUMAN Q9Y5A9 GNGVGQSQAGSG 368 1 YTH domain family protein 2 STPSEPHPVLEKLR 381 YTHD2_HUMAN Q9Y5A9 GQSAFANETLNK 167 1 YTH domain family protein 2 382 YTHD2_HUMAN Q9Y5A9 GQSAFANETLNK 167 1 YTH domain family protein 2 APGMNTIDQGMA ALK 383 YTHD2_HUMAN Q9Y5A9 GQSAFANETLNK 167 1 YTH domain family protein 2 APGMNTIDQGMA ALKLGSTEVASN VPK YTHD2_HUMAN Q9Y5A9 368 1 YTH domain family protein 2 YTHD3_HUMAN Q7Z739 169 1 YTH domain family protein 3 YTHD3_HUMAN Q7Z739 169 1 YTH domain family protein 3 ZAP70_HUMAN P43403 291 1 Tyrosine-protein kinase ZAP-70 ZBT34_HUMAN Q8NCN2 140 1 Zinc finger and BTB domain-containing protein 34 384 ZBT44_HUMAN Q8NCP5 GSISPVSSECSVVER 158 1 Zinc finger and BTB domain-containing protein 44 ZC11A_HUMAN O75152 349 1 Zinc finger CCCH domain- containing protein 11A ZC11A_HUMAN O75152 531 1 Zinc finger CCCH domain- containing protein 11A ZC3H4_HUMAN Q9UPT8 68 1 Zinc finger CCCH domain- containing protein 4 ZC3H4_HUMAN Q9UPT8 742 1 Zinc finger CCCH domain- containing protein 4 ZC3HD_HUMAN Q5T200 160 1 Zinc finger CCCH domain- containing protein 13 ZC3HD_HUMAN Q5T200 160 1 Zinc finger CCCH domain- containing protein 13 385 ZC3HE_HUMAN Q6PJT7 GVPSPPGYMSDQ 524 1 Zinc finger CCCH domain- EEDMCFEGMKPV containing protein 14 NQTAASNKGLR 386 ZCCHV_HUMAN Q7Z2W4 GVATDITSTR 434 1 Zinc finger CCCH-type antiviral protein 1 387 ZCCHV_HUMAN Q7Z2W4 SLSDVTSTTSSR 492 1 Zinc finger CCCH-type antiviral protein 1 388 ZCH18_HUMAN Q86VM9 TVLEPYADPYYD 362 1 Zinc finger CCCH domain- YEIER containing protein 18 ZCHC2_HUMAN Q9C0B9 235 1 Zinc finger CCHC domain- containing protein 2 389 ZCHC8_HUMAN Q6NZY4 GETEVGEIQQNK 344 1 Zinc finger CCHC domain- containing protein 8 390 ZEB1_HUMAN P37275 AADCEGVPEDDL 50 1 Zinc finger E-box-binding PTDQTVLPGR homeobox 1 ZF161_HUMAN O43829 244 1 Zinc finger protein 161 homolog ZF161_HUMAN O43829 244 1 Zinc finger protein 161 homolog ZFAN6_HUMAN Q6FIF0 107 1 AN1-type zinc finger protein 6 ZFAN6_HUMAN Q6FIF0 127 1 AN1-type zinc finger protein 6 ZFPL1_HUMAN O95159 172 1 Zinc finger protein-like 1 391 ZFX_HUMAN P17010 GTCPEVIK 245 1 Zinc finger X-chromosomal protein 392 ZFX_HUMAN P17010 GTCPEVIKVYIFK 245 1 Zinc finger X-chromosomal protein ZFY16_HUMAN Q7Z3T8 535 1 Zinc finger FYVE domain- containing protein 16 ZFY16_HUMAN Q7Z3T8 108 1 Zinc finger FYVE domain- containing protein 16 ZFY16_HUMAN Q7Z3T8 284 1 Zinc finger FYVE domain- containing protein 16 393 ZMYM3_HUMAN Q14202 STESIPVSDEDSD 256 1 Zinc finger MYM-type AMVDDPNDEDFV protein 3 PFRPR ZMYM4_HUMAN Q5VZL5 929 1 Zinc finger MYM-type protein 4 ZN143_HUMAN P52747 183 1 Zinc finger protein 143 ZN143_HUMAN P52747 152 1 Zinc finger protein 143 ZN200_HUMAN P98182 189 1 Zinc finger protein 200 ZN264_HUMAN O43296 160 1 Zinc finger protein 264 ZN277_HUMAN Q9NRM2 7 1 Zinc finger protein 277 ZN346_HUMAN Q9UL40 14 1 Zinc finger protein 346 394 ZN644_HUMAN Q9H582 SFGSPLGLDKR 616 1 Zinc finger protein 644 395 ZN644_HUMAN Q9H582 SFGSPLGLDKRK 616 1 Zinc finger protein 644 ZN646_HUMAN O15015 1006 1 Zinc finger protein 646 ZN787_HUMAN Q6DD87 231 1 Zinc finger protein 787 396 ZN828_HUMAN Q96JM3 AIDDQKCDILVQE 586 1 Zinc finger protein 828 ELLASPK 397 ZN828_HUMAN Q96JM3 AIDDQKCDILVQE 586 1 Zinc finger protein 828 ELLASPKK 398 ZNF24_HUMAN P17028 SILIIPTPDEEEKILR 10 1 Zinc finger protein 24 399 ZNF24_HUMAN P17028 SILIIPTPDEEEK 10 1 Zinc finger protein 24 ZNF76_HUMAN P36508 14 1 Zinc finger protein 76 ZNHI2_HUMAN Q9UHR6 145 1 Zinc finger HIT domain- containing protein 2 ZNHI2_HUMAN Q9UHR6 145 1 Zinc finger HIT domain- containing protein 2 ZYX_HUMAN Q15942 150 1 Zyxin 400 ZYX_HUMAN Q15942 SLSSLLDDMTK 150 1 Zyxin 401 ZYX_HUMAN Q15942 SLSSLLDDMTKN 150 1 Zyxin DPFKAR

TABLE 2 Mass spectrometry statistics for identified caspase-derived peptides. Swiss-Prot acc # m/z z Error ppm score E value Q13362 695.0352 3 −8.3 60.6 2.80E−06 P29372 833.0408 3 −3.3 44.3 6.30E−05 P11171 756.4105 4 21 51.9 4.30E−08 P11171 663.9429 5 −2.3 62.5 2.50E−09 Q13541 938.7966 3 6.1 55.9 2.30E−07 Q13542 952.7778 3 −2.4 55 1.80E−08 Q6S8J3 737.909 2 −1.2 24.9 0.0013 A5A3E0 P62736 Q562R1 P60709 P68032 P63261 P63267 Q9BYX7 P68133 Q6S8J3 586.3246 2 −0.82 30.7 2.60E−04 A5A3E0 P62736 Q562 P60709 P68032 P63261 P63267 Q9BYX7 P68133 Q6S8J3 600.9496 3 1.2 43.4 9.70E−06 P60709 P63261 Q9BTE6 682.349 3 −6.1 48.5 4.10E−04 P00519 640.3181 3 −5.7 56 1.70E−05 O14639 657.989 3 5.1 45.6 8.30E−06 Q96P50 836.3983 2 −14 42.9 5.50E−07 Q9UKV3 1144.8881 3 0.63 24.3 0.092 Q9UKV3 541.5953 3 3.6 39.8 2.20E−05 Q9UKV3 378.2309 3 27 28.4 0.0014 Q9UKV3 627.2832 2 4.8 34.5 0.009 P21399 812.425 2 −1.4 23.4 4.10E−04 O95573 612.8007 2 −8.2 39.5 0.014 O60488 P62736 662.8276 2 −0.9 34.1 3.00E−06 P60709 P68032 P63261 P63267 P68133 P62736 584.7781 2 0.66 38.2 5.90E−06 P60709 P68032 P63261 P63267 P68133 P60709 638.5862 4 −2.9 42.2 1.80E−06 P63261 P60709 615.0721 4 −11 40.9 4.10E−07 P63261 P12814 1108.499 3 0.83 30.6 2.10E−04 P12814 1103.1478 3 −17 22.4 0.011 P12814 667.8556 2 3.7 41.5 0.096 P35609 Q08043 O43707 P35611 996.1574 3 −18 33.4 4.90E−05 Q6ZN18 396.7168 2 6.6 28.8 0.023 Q96SZ5 1006.9929 2 1.9 22.8 0.0013 Q8N4X5 770.9177 2 −5.7 42.4 2.80E−04 Q8N4X5 604.6598 3 −0.055 39.4 0.019 Q8N4X5 415.2028 3 −1.2 28.2 0.02 Q6ULP2 401.8817 3 19 29.6 0.085 Q8N302 432.7184 2 9.9 28 0.0053 Q8N302 439.4802 4 9.6 32.2 3.70E−04 Q8N302 534.2534 3 −9.1 32.4 0.0061 Q09666 794.9363 2 −2.5 23.4 9.00E−04 Q09666 514.2765 2 3.8 31.7 0.0041 Q09666 416.5694 3 −4.7 31.8 0.005 Q09666 598.7812 2 −20 38.5 0.068 Q09666 463.9146 3 −5.8 44.8 0.013 Q09666 481.7599 2 −19 29.6 0.052 Q09666 496.2643 2 −25 24.4 0.058 Q09666 388.9439 4 −0.37 39.1 3.00E−04 Q09666 519.9274 3 −1.2 48.4 5.60E−04 Q09666 397.2338 3 −5.9 29.2 0.0027 Q09666 446.888 3 −7 30.8 0.025 Q09666 439.2175 3 −3.9 32 0.0024 Q09666 596.7931 2 −4.6 39.1 0.055 Q09666 514.9217 3 −13 40.8 0.0015 Q09666 583.2912 2 1.3 40.7 0.041 Q09666 583.2881 2 −4 37.2 0.048 O95433 788.8887 2 −9.6 37.5 6.50E−05 O95433 547.0416 4 5.6 30.2 2.80E−04 O95433 593.2786 3 9.7 43.6 8.50E−05 Q8WYP5 960.9803 2 −0.86 36.5 5.00E−06 Q9Y4K1 571.6341 3 3.7 57.2 3.60E−06 Q9Y4K1 904.4601 3 −1.9 26.4 0.026 Q02952 596.9709 3 −1.9 35.8 0.02 Q9Y2D5 530.78 2 −9.9 22.1 0.027 Q99996 476.256 2 12 34.5 4.80E−04 Q99996 468.2558 2 6.9 35.5 0.0067 Q7Z591 438.5817 3 10 42.8 2.70E−05 Q12802 737.6817 3 −4.9 46.5 1.60E−04 Q12802 772.363 4 −3.1 44.8 4.50E−05 Q12802 562.265 3 −4.8 35.9 3.00E−04 Q12802 474.2589 2 6.4 34.5 0.0039 Q12802 917.9474 2 −7 52.6 1.00E−05 Q12802 848.4239 2 2 29.9 0.052 Q9ULX6 707.3197 2 5.1 40.1 3.20E−05 Q8TCU4 716.8455 2 −0.84 39.6 6.80E−05 Q8TCU4 530.2837 4 −2.8 30 0.005 Q8TCU4 556.8022 2 2.3 25.9 3.30E−04 Q9HCF4 527.7967 2 −2.9 36.4 4.40E−04 Q9HCF4 684.3854 2 −0.51 23.9 0.0017 Q9HCF4 878.4746 2 −0.13 30.8 6.10E−06 Q01432 1012.9898 2 −14 42 6.50E−05 P53582 608.6207 3 1.5 49.8 7.80E−07 Q8IWZ3 632.3286 5 14 26.7 0.007 Q8IWZ3 933.4111 2 −19 22 2.60E−04 Q68DC2 518.28 3 −7.5 43 0.0026 Q92625 440.5292 3 −5.1 36 7.90E−04 P07355 494.2418 3 2.7 38.9 1.10E−04 A6NMY6 O43747 867.4424 3 −4.5 51.8 5.70E−08 O75843 833.4361 5 −5.6 34.6 0.0022 O94973 679.9964 3 −6.4 49.5 3.40E−06 Q13367 608.3474 4 −6.1 22.8 0.041 Q13367 910.0015 2 −0.16 39.4 7.10E−05 Q92870 792.7011 3 −1.8 43 2.10E−04 P25054 957.4693 3 −11 52.5 4.50E−09 Q9HDC9 475.7311 2 −2.9 33 0.084 Q7Z2E3 891.0972 3 −8.3 50 3.20E−06 Q3SXY8 1169.6076 3 2 31.7 0.0066 P25098 491.9294 3 5.4 36 0.0013 P25098 619.6332 3 −3.3 31.5 1.70E−04 P35626 P25098 779.8454 2 −4.6 32.2 8.90E−07 P35626 Q92888 398.8444 3 −47 26.6 0.0068 Q92974 711.8592 2 4.6 32.7 1.10E−04 O15013 1053.8212 3 −24 23.4 2.10E−04 O14497 830.8775 2 −0.32 22.6 3.00E−05 O14497 822.8813 2 1.2 29.3 1.50E−06 O14497 774.0026 3 −6.1 65.8 1.40E−07 P29374 796.8669 2 2.8 36.1 2.90E−06 Q4LE39 1357.619 3 2.2 28.9 2.60E−05 Q68CP9 710.3607 4 −2.5 34.7 2.40E−05 Q68CP9 652.071 4 −11 23.6 0.0054 Q8N2F6 915.4348 2 3.9 49.2 2.40E−04 Q6NXE6 969.2285 4 −0.03 23.1 0.046 Q6NXE6 965.2247 4 −5.3 42.8 1.40E−06 P27540 621.6545 3 17 41.6 4.50E−04 Q9UBL0 663.9974 3 −13 43 3.50E−06 P61160 567.7937 4 −2.9 25.9 0.0085 P61158 694.0126 3 −2 34.8 1.00E−03 O15511 952.3894 2 −20 61.5 3.00E−08 O15511 837.8722 2 −0.95 43.1 3.90E−08 Q9BXP5 406.8858 3 8.5 32.4 4.10E−04 Q8WXK3 817.952 2 −0.3 26.3 6.10E−04 Q8N9N2 1067.091 3 −15 36.1 8.00E−07 Q9H1I8 709.3174 3 5.1 64.5 6.50E−08 Q9BVC5 476.7547 2 7.9 27.4 0.016 Q13625 884.4693 3 −0.001 28.5 0.0026 Q96QE3 990.488 2 1.2 22 0.003 Q9ULI0 761.9025 2 0.34 27.9 2.30E−04 P18846 378.2114 4 −17 28.1 0.0012 P18848 866.4062 3 −5.7 45.6 2.90E−06 P17544 742.397 2 −17 42 0.0031 P17544 624.6849 3 −10 27.6 0.01 Q9NT62 706.7647 5 0.57 29.7 0.0033 Q9NT62 790.3876 3 3.1 58.8 1.30E−06 Q9Y4P1 687.847 2 −2.3 43.1 0.0069 P46100 689.0362 3 0.84 34 5.70E−04 P0C7T5 631.8268 2 −1.9 27 7.30E−04 Q8WWM7 878.4225 2 −5.3 55.1 2.70E−07 Q8WWM7 870.4253 2 −5 50.7 3.20E−05 Q99700 1189.2343 3 4.8 26.6 0.0068 P54252 839.8587 2 −7.4 40.4 3.10E−04 Q9UPN4 971.4637 3 −11 30.2 6.50E−06 Q9Y520 832.8634 2 −8.3 40.2 2.20E−06 Q9Y520 716.0153 3 0.7 49.7 5.50E−06 Q92560 759.3601 3 −2.9 31.8 0.0062 P51572 479.5827 3 −3.1 42 6.90E−05 P51572 552.5266 4 −4.3 52.9 2.30E−08 P80723 660.9797 3 5.1 49.9 1.20E−05 P80723 494.9073 3 0.21 43.6 3.50E−04 P46379 1087.21 3 −7 37.4 3.70E−05 P46379 1129.9151 3 −0.73 37.4 6.60E−06 Q9NRL2 678.316 3 −11 24.9 0.0029 Q6ZUJ8 750.3245 2 2.2 57.3 4.20E−04 Q6ZUJ8 721.6722 3 2.1 49.5 1.40E−05 Q9NYF8 528.2364 2 1.5 29.8 0.021 Q9NYF8 437.5387 3 9 32.9 3.40E−04 P11274 682.3057 2 −6.1 24.6 6.20E−04 A6H8Y1 803.4489 2 −3.3 29.3 2.90E−04 P55957 581.2888 2 −3.7 39.6 0.0038 Q5TH69 385.5289 3 15 28.2 0.0034 O00499 542.2935 2 0.33 31.9 8.20E−04 Q9NR09 398.861 3 −5.4 26.8 0.025 Q6QNY0 878.9029 2 −2.2 40.9 0.0018 Q8WV28 1031.4701 3 −1.6 34.3 4.70E−05 Q12982 933.0836 3 −4 37.9 6.20E−05 Q12830 613.3208 2 2.6 44.1 0.027 O95696 624.8586 2 21 25 0.0048 O60885 424.5384 3 −0.75 32.9 0.0026 Q9H0E9 597.9905 3 4.6 52 8.20E−05 Q96RE7 420.8942 3 10 29.4 0.037 O43683 463.2503 2 13 28.4 0.0023 Q43683 835.4028 2 −3.2 28.7 4.70E−06 Q9BRD0 740.8795 2 −19 46 0.0071 Q96L14 832.4292 2 0.79 24.5 3.60E−04 Q07021 904.0546 3 −3 48.5 4.20E−09 O14523 567.6593 3 −1.2 49.4 7.10E−06 Q6P1N0 1118.5371 3 −15 52.9 4.20E−08 Q6P1N0 1113.2059 3 −14 52 2.70E−08 Q5T0F9 550.814 2 −9.3 39.7 0.0015 Q5T8I9 516.7592 2 0.29 28.6 0.031 Q5T8I9 619.8312 4 1.9 30.4 0.0013 Q5T3J3 741.8712 2 −1.3 22.9 7.10E−05 Q5T3J3 1040.5147 2 4.5 26.6 1.70E−04 Q96BR5 721.3472 2 −3.2 27.7 1.10E−04 Q7L4P6 579.2901 3 3.5 31.4 2.90E−04 Q5SV97 881.8479 5 −5.2 23 0.028 Q68CQ1 552.8186 2 −10 34.7 0.071 Q08AD1 578.2992 2 6.8 36.9 0.016 Q9BTV7 579.3169 4 22 36.9 1.50E−04 Q9P1Z2 674.3779 2 −2.5 47.5 2.10E−05 P19022 547.86 2 −2.8 22.4 0.0049 P19022 368.5621 3 13 24.2 0.0094 Q13111 661.5167 5 16 51 9.80E−09 Q13111 449.2444 2 3 25.6 0.021 Q13111 919.9718 2 0.46 35.5 1.30E−06 P27797 631.8193 4 −2.6 51.1 1.10E−06 P27797 911.7541 3 −7.3 34.9 5.90E−04 P27797 870.0258 3 −6.1 54.5 1.90E−07 Q8NCB2 865.9321 2 0.86 25.9 2.90E−05 P49069 642.0082 3 −0.29 26 0.0051 P49069 644.9868 3 −3.2 62.1 2.40E−06 P49069 747.6898 3 −14 48.1 1.50E−05 Q5T5Y3 487.9148 3 −0.65 28.9 5.30E−04 Q5T5Y3 686.1413 5 2.1 27.1 9.90E−04 Q5T5Y3 779.045 3 −1.6 52.6 1.10E−05 Q14444 642.6701 3 −0.51 51.8 2.30E−07 P47756 418.2392 3 11 33.5 5.90E−04 O15234 513.2743 3 4.9 30.6 6.70E−05 Q8NG31 810.8847 2 −4 32.6 1.20E−06 P42574 667.3261 2 13 41 0.0012 P42574 500.8599 3 −5.2 39.2 1.30E−05 P42574 495.5289 3 −3.9 30.9 1.00E−04 P55210 671.3188 2 −6.7 54.1 3.20E−05 Q13948 525.3142 3 5.1 29.9 4.40E−04 P39880 P07858 456.5788 3 −7.3 36.9 0.036 Q9H6R7 954.0162 2 0.98 46.1 5.70E−07 P22681 689.8437 4 −4 37 3.20E−06 Q9BRT8 479.7709 2 3 32.6 0.072 Q8IUF1 Q5JTY5 Q5RIA9 Q4V339 A6NM15 Q96G28 559.2568 3 4.8 27.2 0.0029 Q96G28 553.9217 3 −1.5 29.9 4.00E−04 Q96G28 467.5685 3 13 24.4 0.0025 Q96G28 527.9086 3 0.77 40.9 3.70E−05 Q96CT7 546.7925 4 20 27.8 0.0032 O60293 563.6239 3 0.51 42.9 2.20E−05 Q9NV96 577.7865 2 2.9 52.4 2.10E−04 Q96MW1 736.8328 2 2 51.9 5.60E−05 Q9Y3C0 776.4054 2 −3.3 47.6 0.007 Q7Z6B0 791.9203 2 −1.9 38.8 0.005 Q96F63 734.3549 3 −5.2 26.5 0.0023 Q9Y3X0 616.3044 3 −1.6 38.3 6.50E−06 Q9Y3X0 507.7253 4 −30 33 8.60E−05 O60583 768.8993 2 −0.24 34.5 4.40E−05 O60583 1060.8711 3 −1.4 31.1 0.0011 P21127 807.4354 2 −9.3 54.5 1.70E−07 P21127 737.069 3 −8.6 47.5 1.10E−07 Q14004 628.3353 2 −0.65 30.1 5.10E−05 P30260 1014.5668 2 2 29.5 1.10E−04 P30260 762.4204 2 1.3 51.1 0.001 Q99459 571.2824 2 −5.4 37.5 0.0019 Q9BWT1 657.8024 2 −7.4 37.5 5.80E−05 Q9UKY7 725.3042 2 −3.5 33.7 9.40E−05 Q9Y232 1439.7215 3 −0.52 42.5 3.20E−06 Q49AR2 586.9478 3 8.5 41.8 2.40E−05 O94986 626.0437 4 −6.9 36 1.90E−04 Q5SW79 870.4244 3 −12 50.5 2.10E−06 Q5SW79 1117.558 3 1.1 26.3 0.0077 Q5SW79 559.9728 3 1.3 24.6 0.015 Q03701 869.0709 3 0.25 24.2 0.001 Q03701 445.2475 2 7.5 22.2 0.023 Q03701 608.79 2 −1.6 40 0.0048 Q6NXR4 1017.8124 3 1.6 25 0.016 Q6P1X6 774.3731 2 −3.8 29.5 2.90E−06 P10809 698.8351 2 2.1 38 5.30E−04 P10809 538.3097 2 1.4 33.2 0.0055 P10809 594.2953 2 −5.8 39.6 0.0068 P10809 528.3024 4 0.58 23.6 0.02 Q12873 1130.1293 3 −7.1 40.5 5.50E−07 Q14839 Q8TDI0 Q14839 568.7467 4 0.63 38.4 3.10E−06 Q14839 686.0461 4 −24 34.5 3.20E−05 Q9P2D1 777.361 3 12 51 1.80E−06 Q9BY43 618.8337 2 1.5 34.6 0.0014 Q9H444 Q96CF2 Q9NRY2 546.9371 3 −0.91 40.1 3.80E−04 Q5VWN6 526.2781 2 11 40.6 3.00E−04 Q86WR7 931.142 3 7.8 55.6 3.50E−09 Q6IAA8 598.2323 3 −4.3 29.2 0.0064 Q6IAA8 592.907 3 6.4 23.6 0.041 Q9HCM1 701.8622 2 −0.14 27.8 5.00E−05 Q9HCM1 741.8753 2 −2.8 43.8 0.064 Q96C57 688.8449 2 1.5 26.1 3.70E−04 Q96C57 832.9297 2 −0.19 27.4 7.50E−04 Q96C57 824.9339 2 1.8 31.3 8.30E−06 Q96C57 953.0076 2 −1.6 23.2 3.70E−04 Q7Z460 612.289 2 4.7 39.3 0.0017 Q7Z460 684.6447 3 −8.9 39.5 7.40E−05 P09496 1039.7784 3 −5.5 63.1 4.30E−10 P09496 1034.4414 3 −11 59.2 1.40E−10 P09496 680.3305 2 −0.11 40.2 6.10E−04 O00299 917.4094 3 −18 29.1 2.90E−04 P30622 487.59 3 4.3 24 0.038 Q9HAW4 940.0497 2 1.2 32.6 5.20E−06 Q15003 534.2601 2 8.6 40.5 8.00E−04 Q15003 708.3025 4 2.1 29.7 1.50E−05 Q15003 461.5532 3 0.11 36.7 7.50E−06 Q15003 394.2029 3 17 25.1 0.02 Q15003 624.776 2 2.7 34.2 2.60E−05 Q6IBW4 578.9792 3 1.3 35.7 6.90E−04 P12111 1063.8161 3 −21 30.7 0.0079 Q53SF7 889.4591 2 3.8 44 6.80E−04 P53621 914.9333 2 −0.38 53.3 5.70E−07 P53621 650.848 2 8 29.3 0.0038 P35606 603.5815 4 20 35 0.0012 P31146 455.7318 2 −12 23.2 0.033 Q1ED39 484.2491 4 5.1 25.1 0.02 Q7Z7A1 838.9225 2 −2 29.1 4.20E−05 Q7Z7A1 482.9271 3 −2.3 30.2 0.017 Q6FI81 556.5493 4 11 29.9 2.10E−04 Q99829 494.2491 2 −9.9 31.4 0.011 O75131 602.3151 2 1.1 23.1 6.90E−04 Q16630 724.8665 2 −0.77 47.3 0.027 Q8N684 721.3527 3 0.039 26.5 8.10E−04 Q8N684 682.6449 3 −4.8 44.1 2.70E−06 Q8N684 770.3681 2 0.24 42.4 0.0031 Q6JBY9 908.7383 3 −4.8 61.4 1.10E−08 Q96N21 1176.6536 2 3.3 24.7 2.30E−04 Q53F19 666.9666 3 −2.1 24.7 0.096 Q53F19 744.8885 2 −14 46.5 1.80E−04 Q96B23 779.3919 3 −6.8 31.3 5.20E−04 Q96B23 727.367 3 4.8 38.3 1.30E−04 Q96B23 779.3968 3 −0.56 28.3 0.0065 Q96B23 722.0345 3 3.7 40.8 8.90E−05 Q96B23 774.055 3 −14 40.5 3.00E−04 P16220 961.8356 3 −14 49.5 4.30E−07 P16220 425.2108 2 −20 32.1 0.084 P16220 503.2726 2 5.5 32.5 0.06 Q5TZA2 493.88 3 −1.8 30.5 8.70E−04 Q9BQ61 595.811 2 4.6 31.2 0.014 Q9H6X5 782.024 3 −14 32.4 2.60E−05 Q13098 820.4062 3 −2 61.5 1.10E−08 Q9H175 672.7048 3 −6.2 37.6 1.30E−05 Q12996 652.331 4 −6.2 39.9 2.20E−04 Q8WYA6 781.3392 3 −0.45 53.5 1.30E−07 P49711 1069.8452 3 −6.1 38.2 1.20E−07 P49711 1069.8381 3 −13 44.6 2.10E−07 P49711 1064.5039 3 −15 50.7 7.00E−09 P35222 415.2119 3 2.6 29 0.0089 O60716 747.7031 3 −8.9 56.8 3.80E−06 Q6PD62 498.719 4 −7.4 40.8 5.00E−05 Q13620 706.335 2 −5.1 42.6 3.60E−05 Q9NTM9 573.7935 2 4.2 40 8.60E−04 P39880 962.4311 2 4.9 44.1 1.30E−05 O43169 622.9469 3 −32 33.8 7.10E−05 P16989 510.6162 3 10 46.8 1.10E−06 P16989 443.2429 2 −0.47 27.6 0.0021 P16989 892.1155 3 14 51.2 8.10E−06 P16989 761.8609 2 −8.2 27.4 0.0011 P67809 Q9Y2T7 Q6PH85 533.2533 3 3.8 43.5 7.00E−05 Q14203 607.9659 3 6.1 45.5 3.10E−05 Q9NUU7 801.4011 2 −14 26.5 0.014 Q92499 705.915 2 0.84 31.6 2.50E−06 Q9GZR7 1184.5992 2 1.4 34.7 2.00E−05 Q7L014 809.1259 3 1.5 36.2 1.10E−04 Q7L014 424.872 3 3.7 29.6 0.063 Q7L014 755.8863 2 −2 53.1 2.50E−05 Q7L014 747.891 2 1 39.1 2.00E−04 Q5T1V6 601.8233 2 1.4 40.5 0.0018 P17661 490.2534 3 −0.52 23.6 0.0019 P17661 484.9203 3 −3.5 29.6 0.011 O00273 550.2886 2 −3.9 28.9 0.022 O00273 452.2561 2 17 36 0.037 O00273 667.8635 4 2.2 22 0.041 Q8WYQ5 643.3443 2 −0.52 23.3 0.0055 Q8WYQ5 926.1158 3 −4.6 49.6 5.40E−09 Q8WYQ5 920.7767 3 −13 53 2.90E−09 Q8WYQ5 987.1671 3 1.2 24 0.063 Q86XP1 1012.8194 3 −1.8 31.6 2.40E−04 Q86XP1 702.3881 3 −10 53.1 3.80E−09 Q8NCG7 802.0843 3 1.3 63 1.10E−07 Q3LXA3 543.7521 2 −8.5 31.8 0.0026 Q3LXA3 414.8688 3 −12 35.1 3.30E−04 Q7L2E3 519.2635 4 8.9 24.4 2.10E−04 Q8IY37 996.1776 3 −11 34 0.001 Q08211 629.989 3 9.3 39.7 0.0011 Q08211 890.1142 3 −0.28 56.1 2.20E−09 Q08211 884.7845 3 1.9 57.3 1.60E−09 O60610 918.5204 4 11 35.9 9.30E−04 Q9BTC0 865.1213 3 −16 35.4 6.10E−05 Q9BTC0 553.7901 2 16 33.1 8.20E−04 Q9BTC0 796.7609 3 3.5 60.2 2.70E−08 Q9BTC0 877.7758 3 −26 45.1 5.70E−07 Q9BTC0 399.519 3 4.9 24 0.012 Q12959 1189.5762 3 −0.17 25.8 0.0075 Q99615 709.0066 3 2.2 34.6 5.40E−05 Q99615 761.0354 3 −4.4 40.5 1.00E−05 Q99615 703.6769 3 5.1 66 1.10E−06 Q99615 755.7119 3 6.4 55.9 1.10E−06 O00429 665.3303 2 −0.93 29.1 8.40E−05 O00429 605.5967 3 −2.2 51 1.50E−05 O00429 657.6226 3 −14 34.5 1.40E−04 O00429 600.2747 3 14 49.7 1.40E−05 O00429 652.2982 3 −2.9 47.1 1.40E−04 Q9Y6K1 573.5599 4 7.5 38.5 1.10E−04 Q96BY6 709.3342 2 −6.7 30.3 3.40E−06 Q9BU89 563.8221 2 −8.6 29 0.0021 Q9BU89 607.3488 3 −3.8 59.6 1.70E−07 Q8TEK3 826.1048 3 2.2 30.7 0.0027 Q9UKG1 1025.8137 3 −23 53.4 1.20E−07 P28340 599.9963 3 19 43.9 5.90E−07 P28340 627.3408 4 −11 36 1.80E−05 P09884 525.7645 2 0.34 36.6 0.0066 Q86TI2 604.7786 2 −3.6 43.1 0.0049 O14531 407.887 3 4.7 23.4 0.067 Q16643 780.8959 2 −1.2 23.7 0.0024 Q16643 1009.9798 2 −2.1 47.6 2.60E−05 P55265 659.9648 3 −5 39.8 4.40E−06 Q9NZJ0 824.8967 4 −7.2 41.2 3.10E−06 Q9NZJ0 720.5584 5 4.3 44.5 1.80E−06 Q8TDB6 660.31 2 −1.6 24.5 0.0062 Q14204 510.5649 3 0.026 28.9 0.0014 Q14204 600.2835 2 1.4 35.5 0.072 Q6ZTU2 936.4917 3 −6.9 43 7.70E−05 Q96L91 O43491 1026.8482 3 −4.4 24.5 0.027 Q9H1B7 812.954 2 −0.63 34 1.70E−06 Q99848 551.2859 3 −0.34 44 4.20E−04 P42892 813.3829 3 −1.2 46.7 1.30E−04 Q9H8V3 648.8259 2 −2.4 22.2 0.013 Q6P2E9 1036.5319 4 25 32.1 6.80E−04 Q6P2E9 833.9083 2 1.7 36 1.10E−06 Q6P2E9 825.9041 2 −6.5 35.5 8.70E−07 Q6P2E9 557.6229 3 0.72 27.7 0.036 Q6P2E9 700.021 3 −5.3 51.3 1.70E−07 Q6P2E9 760.3679 3 −3.6 55.8 6.80E−07 Q6P2E9 428.8875 3 −4.9 29.4 0.0077 Q3B7T1 881.4229 2 −6.5 39 1.50E−05 Q3B7T1 945.4758 2 −0.38 34.9 2.10E−07 Q15075 907.7752 3 −3.8 22.9 0.009 Q15075 1124.5314 3 −9.8 48.8 1.30E−07 P68104 941.1216 3 −7.7 44.6 1.40E−05 Q5VTE0 P68104 790.0424 3 −0.28 29.8 0.0025 Q5VTE0 P68104 784.7067 3 −5.5 43.6 2.90E−07 Q5VTE0 P68104 674.3309 3 0.44 22.5 0.076 Q5VTE0 P68104 479.2559 4 −13 25.3 0.018 Q5VTE0 P68104 850.3883 3 −0.24 43.8 3.20E−06 Q5VTE0 P24534 609.2763 3 3.1 45.2 4.80E−07 P24534 917.8751 2 −3.9 43.7 2.30E−05 P29692 613.2911 4 −0.12 33.8 1.70E−06 P29692 734.3377 3 −0.37 43.6 2.50E−05 P13639 515.6041 3 4.1 63 3.40E−05 Q8N3D4 951.4455 3 8.8 52.1 6.90E−08 Q8NDI1 843.3957 3 −2.4 45.2 1.10E−05 Q9H4M9 1034.4543 3 −3.1 52.4 3.10E−08 Q9H9B1 576.9345 3 −2.7 40.8 9.40E−05 Q9H9B1 702.3415 2 −0.92 28.2 1.10E−04 Q96KQ7 491.9357 3 5.6 44 1.20E−04 P55884 735.3623 2 −3.9 42.1 0.0024 P55884 683.7148 3 −2 44 1.80E−04 O75821 741.8482 4 −2.3 38.9 1.10E−05 O75822 667.7986 4 −6.4 39.9 6.20E−06 P32519 858.9174 2 −12 60.5 2.40E−06 P32519 850.9296 2 −0.21 44.1 3.40E−06 P06733 905.1272 3 −14 34.6 4.50E−04 P14625 554.7924 2 2.6 32.2 0.085 P14625 599.2788 2 −11 32.4 0.004 P14625 480.912 3 17 30.3 1.90E−04 Q9UBC2 806.7389 3 5.3 57.4 1.20E−06 P42566 843.0613 3 9.5 29.7 0.0043 Q9H2F5 594.3092 2 −4.7 24 8.10E−05 Q9Y6I3 538.6288 3 4.5 37.7 0.0043 O95208 638.8329 2 4.2 32.2 5.10E−04 Q2NKX8 551.6196 3 −2.8 22.4 0.056 Q03468 745.3792 2 5.7 23.2 0.0012 P15170 674.8093 4 −0.88 28.4 0.0016 P15170 533.6556 5 7.9 35.3 1.30E−05 P15170 569.8814 5 39 25 0.0013 P15170 712.066 4 −8.1 48.1 5.00E−06 P50548 807.3873 2 1.2 27.3 0.0017 Q86X53 531.277 2 −0.54 26.6 0.0036 A0FGR8 745.9169 2 3.5 43 0.022 Q7Z2Z2 390.1911 3 15 31.6 3.60E−04 Q7Z2Z2 589.2464 2 2.2 40.2 0.005 Q9NVH0 440.2091 3 13 25.1 0.0051 Q8N5W9 739.3938 3 −8.5 42.5 1.00E−06 Q9H098 660.663 3 1.7 31.1 7.20E−04 Q6P1L5 438.2587 3 1.5 32.9 5.20E−04 Q96EY5 466.9291 3 2 45.8 4.70E−04 Q9Y6X4 667.8344 2 −5.3 23.7 9.90E−04 O94988 507.2676 3 3.8 31.8 0.0025 O94988 567.6108 3 −1.3 55.4 2.50E−06 Q641Q2 809.892 2 3.7 49.8 2.60E−05 Q5SNT6 Q9Y4E1 Q5SRD0 Q7Z4H7 671.3426 2 −1.4 41.6 0.077 Q8NFC6 840.4196 3 −3 53.2 5.30E−08 Q8NFC6 513.9373 3 6.4 40.2 3.50E−06 Q8NFC6 758.3617 3 −0.36 56.7 9.50E−08 Q8NFC6 900.7601 3 −8.8 65.1 3.60E−11 Q8NFC6 753.034 3 4.8 67.6 1.20E−08 Q8NFC6 581.7388 2 7.5 26.8 0.0022 P49327 592.9841 3 1.5 46.1 2.00E−04 P02765 480.8913 3 −0.56 30.6 0.0083 Q6UN15 438.8746 3 −1.5 25.1 0.017 Q5T1M5 1176.6186 3 0.9 32.4 1.60E−04 Q5T1M5 994.8491 3 7.8 49 1.40E−06 Q01543 445.8907 3 −8.7 29.2 0.0027 P21333 1143.0476 2 0.52 42.5 1.10E−08 P21333 847.4108 3 −15 30.1 6.30E−04 P21333 768.7155 3 −3.5 39.7 2.50E−05 P21333 571.7673 2 21 33 0.0063 P21333 736.361 2 −1.9 41.3 4.70E−05 P21333 775.7592 3 6.1 56.5 4.50E−08 P21333 638.8862 4 43 50.2 7.30E−10 P21333 793.4324 5 5.1 33.9 5.30E−06 P21333 590.2847 2 −5 38.7 0.048 O75369 Q14315 O75369 484.2596 3 5 23.2 0.0062 O75369 794.721 3 −5.4 35.1 6.40E−04 O75369 816.7023 3 −19 62.4 1.10E−08 O75369 811.3807 3 −6.7 35.3 1.90E−05 Q96RU3 949.8877 2 4.4 50.8 7.00E−09 Q96RU3 941.8855 2 −0.55 58.5 1.90E−07 Q8N3X1 867.4791 3 1.3 39.8 1.60E−06 Q8N3X1 459.7417 2 13 34.1 0.0046 Q8N3X1 535.2756 2 6.3 35.1 5.30E−05 Q9P0K8 479.7612 2 9 40.5 0.0011 P85037 625.3471 3 7.3 60.1 9.10E−09 O43524 1040.3843 2 −15 43.7 5.70E−07 Q8IVH2 636.952 5 −2.6 42 1.70E−06 P42345 429.552 3 3 42.5 0.0038 P42345 472.2454 3 −7.7 44.6 0.012 O94915 508.5913 3 −0.42 37 0.001 Q96AE4 881.4463 2 0.8 48 9.20E−06 Q96AE4 664.6509 3 −0.6 35.5 0.001 Q96AE4 483.2372 2 −1.7 24 0.049 Q92945 Q92945 579.3093 3 0.37 50.4 4.30E−06 Q96I24 793.4292 2 −18 42.7 3.90E−05 Q96I24 912.4542 3 −7.1 58.7 6.70E−07 P35637 911.9938 2 −0.33 39 5.90E−07 P35637 442.8908 3 −8.2 29.8 6.60E−04 P51116 728.3358 4 10 32.3 7.10E−05 O15117 1037.9759 2 2.9 26.4 2.70E−05 O15117 912.7125 3 −1.8 46 1.90E−07 O15117 1007.7678 3 5.8 72.4 1.30E−09 P06241 577.2888 2 9.2 41.4 1.50E−04 Q96QD9 600.7898 2 −7.8 41.3 0.016 Q86V81 Q9Y2I7 663.8579 2 5.5 27.2 2.20E−05 Q9Y2I7 792.423 2 −0.051 41.6 9.10E−07 Q9Y2I7 801.415 3 −6.1 49.2 8.30E−07 P04406 668.6631 3 5.8 33.8 4.90E−06 Q06547 903.133 3 −7.1 22.6 0.0016 Q06547 955.1564 3 −18 39.6 2.10E−04 Q8TAK5 591.8463 2 1.1 33.2 5.50E−04 P07902 479.244 2 2 29.4 0.047 Q14C86 603.2872 3 6.2 52.3 6.50E−08 Q14C86 531.257 4 5.4 37 5.80E−05 P23769 667.8206 4 10 34.6 4.80E−05 Q92538 788.3685 2 4.9 29.6 8.00E−06 Q92538 586.2578 3 −0.41 43.9 2.20E−07 Q9Y5B6 369.5298 3 0.6 28.4 0.0087 Q9BSJ2 857.7569 3 −4.9 50.5 3.70E−04 Q9H3P7 901.5111 4 48 33.2 2.80E−05 Q9H3P7 803.0445 3 1.7 56 7.40E−08 P52566 692.8988 2 −3.2 23.3 4.80E−04 P52566 429.0122 4 12 31.5 1.90E−04 P52566 531.7784 2 2.7 35.2 0.014 P06396 607.7944 2 −2.1 41.5 0.0065 P06396 656.0097 3 6 55.1 1.10E−05 Q8TEQ6 962.1116 3 −8.3 38.8 7.50E−05 Q9NWZ8 659.951 3 −0.54 42 1.70E−06 Q17RS7 940.4229 2 −5.6 23.4 0.0081 Q06210 698.3406 2 −6.1 37.1 3.20E−05 Q9NZ52 1129.5866 3 −26 37.9 1.10E−04 Q9NZ52 690.3595 2 4.6 48.7 0.0065 Q9Y2X7 814.0902 3 −11 29.1 0.0062 Q9Y2X7 807.43 2 6.6 49.5 4.00E−04 Q9Y2X7 581.3222 3 8.6 42 8.70E−05 Q9Y2X7 959.9743 2 −12 39.5 1.60E−04 Q14161 789.7401 3 9.8 53.7 1.20E−04 Q04446 454.1991 3 6.4 30 6.20E−04 O76003 391.8701 3 5 31.2 0.0041 O76003 434.562 3 −10 33.6 0.0058 P14314 966.4078 2 −1.3 33.4 1.20E−06 P14314 730.3231 3 2.8 56.6 7.40E−08 P14314 1200.0392 4 −16 25.1 3.00E−05 P14314 1019.0646 3 −1.6 38.7 3.90E−07 Q9P107 1023.4906 2 0.26 35.9 8.30E−07 Q9P107 460.7289 2 8 38.5 0.0034 Q9P107 713.3512 2 −4 35.2 9.90E−05 P36915 694.827 2 −0.48 36.4 6.90E−05 P36915 820.6503 4 −10 32.4 5.60E−04 P36915 429.2062 3 −19 32.8 0.03 P36915 785.3473 2 1.5 37.5 1.10E−05 P36915 530.2459 3 −7.5 31.4 0.0016 Q14789 907.4273 3 −15 46.6 1.20E−06 Q14789 670.6572 3 −3 29.8 0.0048 Q14789 730.9991 3 −8.1 49.8 2.80E−06 Q3T8J9 806.3869 2 −11 33.4 7.90E−04 Q92917 487.2541 3 3.5 40.5 1.70E−05 Q92917 561.2759 2 30 31.5 0.018 Q92917 542.5193 4 −5.1 40.6 1.00E−07 Q92917 519.2812 2 −7.2 28.6 0.0096 Q92917 603.3236 3 −13 43 1.10E−04 Q9HCN4 578.3334 3 −5.7 33.2 1.40E−04 Q9UKJ3 892.4116 3 −21 43.8 8.80E−06 Q3V6T2 626.54 4 −4.4 51.6 4.20E−06 Q3V6T2 521.2493 2 6.4 34.8 0.061 Q7Z2K8 715.8928 2 −4.6 23 0.0017 P57764 819.9452 2 1.3 36.9 4.10E−06 P57764 889.9305 2 −9.6 40 4.90E−06 P09211 624.7982 2 0.18 30.9 0.0026 P09211 616.7935 2 −12 41 5.70E−04 P78347 590.8117 2 −4 41.8 0.042 P78347 436.9094 3 −1.5 38 0.044 O75367 898.9377 2 −13 44.9 2.30E−05 P62805 552.7883 2 0.87 22.5 0.0064 P62805 420.9007 3 14 36.2 8.00E−04 P62805 463.5985 3 12 37.5 4.60E−04 P62805 432.605 3 16 39.8 2.10E−04 Q13442 376.8892 3 14 23.9 0.017 Q13442 452.5993 3 5.9 28.8 0.0026 Q9Y450 1007.4704 2 −2 40.9 7.90E−05 P14317 483.9191 3 6.6 46.6 3.10E−04 P14317 601.2884 2 −3.3 35 0.048 P56524 603.0072 3 14 38 9.30E−05 P56524 1383.3258 3 1.1 33.9 6.30E−05 Q9UBN7 596.2706 2 17 34.3 0.0016 Q9UBN7 580.2673 2 3.3 39 0.014 Q8WUI4 581.6054 3 −4.4 45.4 3.20E−06 Q9UBI9 440.8914 3 −7.4 35.5 0.0021 Q7Z4V5 737.1483 4 0.079 22.1 0.035 Q7Z4V5 464.9002 3 −5.8 38.6 5.40E−05 Q7Z4V5 459.5666 3 −10 23.2 0.012 Q7Z4V5 386.5469 3 −4.4 31.6 0.0041 Q9ULT8 897.4596 3 −2.3 28.6 0.0036 Q9NRZ9 829.0873 3 −0.68 35.6 3.60E−04 P04233 875.9403 2 −3.4 48 9.20E−05 P04233 867.9434 2 −2.7 47.9 3.30E−04 Q9BW71 515.2498 2 −11 24.4 0.0058 Q8NCD3 583.3096 3 15 44 9.40E−07 Q92619 920.6968 4 −14 26.5 1.20E−04 Q92619 960.4808 2 0.58 43.9 1.20E−05 Q92619 973.9817 2 −15 38.1 1.10E−05 P30519 369.5154 3 4.6 29.4 0.001 P30519 527.8961 3 −24 35.5 3.60E−06 P30519 392.1869 4 6 22.9 0.0017 P31943 871.9425 2 −0.65 34.4 9.70E−05 P31943 513.8811 5 17 32.1 2.10E−04 P55795 P31943 766.0473 3 −8.5 44.4 7.00E−06 P55795 P31943 554.7388 2 0.87 33.5 2.90E−04 P55795 P55795 581.6278 3 −5.7 24.8 0.037 P31942 934.0253 3 −7.3 40.1 3.20E−08 Q9BUJ2 481.8748 3 −15 42.2 1.70E−05 Q9BUJ2 476.5497 3 −1.9 45.5 6.20E−05 Q1KMD3 851.0696 3 1.4 62.6 7.50E−09 Q1KMD3 677.5804 4 3 53.3 7.20E−07 Q8WVV9 567.6299 3 −0.24 37.5 0.0035 Q14103 499.2117 4 −12 41 7.40E−07 P52597 742.3466 2 0.49 43.3 4.60E−04 P38159 574.2536 2 −1.3 36.1 1.50E−05 P38159 495.25 3 1.8 31.5 0.0024 P61978 755.3641 2 3.7 30.5 2.80E−05 P61978 648.0446 4 2.7 55.5 2.80E−10 P61978 1167.8252 3 −10 22.2 7.80E−05 P61978 512.2341 2 7.6 26.4 0.0056 P14866 756.0158 3 −6.8 34.1 1.90E−04 O60506 555.2274 3 −8.2 37 8.20E−05 Q9UJC3 750.3508 2 −4.7 47.6 5.80E−04 Q9UJC3 543.2718 3 2.9 35.7 7.70E−04 Q96ED9 886.8975 2 −12 48.5 2.10E−04 Q9NQG7 1106.7951 3 −14 55.7 8.90E−10 Q03164 898.9001 2 −12 52.9 4.30E−07 Q03164 642.3179 3 15 53.2 1.90E−06 Q03164 972.9138 2 −5.2 46.5 2.70E−06 Q92598 770.0305 3 8.3 53.5 1.90E−07 Q92598 983.132 3 0.38 44 3.50E−06 Q92598 848.1935 4 45 49 2.60E−07 P34931 449.2161 3 15 31.2 0.0019 P08107 P54652 P17066 P48741 P11142 P34932 451.7001 2 0.47 25.9 0.013 P11142 481.7543 2 3.9 29.1 0.011 Q99081 727.3534 2 −10 28.4 0.0028 O43719 911.4252 3 −2.8 42 4.90E−06 O43719 1121.2057 3 0.38 23.7 0.092 O43719 529.2607 3 6.9 39.2 3.90E−07 O43719 736.0272 3 0.37 55.5 1.70E−08 Q7Z6Z7 616.8288 2 −7.3 26.6 0.0025 Q7Z6Z7 656.8401 2 −1.1 24.5 1.50E−04 Q7Z6Z7 486.7675 2 −1.8 31.8 7.00E−04 Q7Z6Z7 559.7913 2 −4.1 31.5 1.40E−04 Q7Z6Z7 826.3566 3 0.28 57.6 1.20E−08 Q7Z6Z7 701.367 3 −4.1 59.6 1.10E−07 Q7Z5L9 683.3163 3 −0.65 57 9.60E−08 P32019 496.2696 2 0.067 31.9 0.07 Q8WUF5 581.6511 3 −0.51 44.7 3.60E−06 P20810 827.8799 2 −13 56.2 1.50E−07 P20810 594.9629 3 2.8 54.1 4.20E−08 P20810 950.9444 2 −5.7 50.5 1.40E−05 P20810 492.0218 4 −7.7 39 6.40E−07 P20810 881.3723 2 −13 52.4 1.20E−06 A6NK07 471.2361 2 −12 28.9 0.063 P20042 O60841 628.8424 2 −5.6 48.6 6.20E−05 O60841 666.0137 3 −3.9 58.6 7.80E−06 O60841 553.5485 4 4.7 48.4 1.60E−06 Q14240 873.395 3 −0.38 56.2 2.40E−06 Q14240 1067.4832 3 −27 48 8.40E−08 P23588 522.9046 3 −35 23.3 0.051 P23588 648.9545 3 6.7 41.1 1.00E−04 Q04637 1290.1025 4 0.97 22.1 0.028 Q04637 680.3351 2 −4.5 43.7 9.10E−04 Q04637 782.3865 2 7.7 49.6 0.01 P78344 544.9423 3 3 49 8.90E−06 P78344 1015.8857 3 4.5 27.8 0.0033 O43432 596.9612 3 −1.8 44.8 3.30E−06 O43432 648.9964 3 0.65 38.5 0.0019 Q15056 903.9804 2 −3.3 40.4 4.10E−06 P63241 761.391 2 −10 39 3.30E−04 P63241 834.8914 2 −4.6 30.1 1.10E−05 Q6IS14 P63241 594.304 3 7.9 47.1 1.80E−05 Q6IS14 P63241 826.8934 2 −5.3 42.9 1.90E−05 Q6IS14 P63241 782.6949 3 −6.5 54.8 2.50E−10 Q6IS14 P63241 654.6412 3 −6 35 3.20E−04 Q6IS14 P63241 795.0175 3 2.1 57.1 1.90E−06 Q6IS14 P63241 832.3709 3 −14 60.6 2.50E−09 Q6IS14 P63241 789.6877 3 4.4 59.2 4.20E−07 Q6IS14 Q9GZV4 778.6994 3 −0.68 54.2 1.50E−07 Q9GZV4 839.0477 3 2.3 35.9 4.20E−05 Q15653 635.8092 2 3.8 43.4 0.0031 Q96HA7 702.685 3 −2.8 47.6 7.60E−08 Q96HA7 566.2926 4 0.63 41.3 9.40E−06 Q13422 718.8969 2 −9.1 57.1 0.002 Q9UKS7 819.8802 2 6.3 38 1.50E−05 Q9H5V7 541.2358 2 13 27.3 0.0031 Q12906 598.0347 4 3.4 39.8 2.50E−08 Q12906 665.7981 2 −1.5 47.2 5.40E−05 Q12906 486.9006 3 0.88 30.9 7.80E−05 Q9H0C8 1055.1788 3 −7.7 33.7 2.00E−05 P52294 671.91 5 −7.6 23.1 0.011 P52294 1168.8793 3 8.3 56.1 1.40E−07 O60684 868.9194 2 −1.2 48.8 1.80E−05 P12268 628.3016 2 −8.2 27.5 0.0019 Q53TQ3 592.8169 2 −0.42 31.4 0.0017 Q27J81 852.7746 3 −13 28.6 4.10E−04 Q27J81 678.866 4 −0.28 32.1 9.10E−05 Q27J81 491.5756 3 10 32.8 6.10E−06 Q96P70 868.9808 2 6.6 46.8 1.90E−04 Q6DN90 668.841 2 0.35 37.6 3.80E−06 P46940 523.2617 4 −7.9 43 1.20E−06 P46940 791.8718 4 −13 48.2 9.70E−10 P14316 481.7287 4 −0.69 37.4 6.40E−07 O14654 569.2558 3 −1.8 56.2 4.30E−05 Q9ULR0 744.8934 2 −10 35 0.002 Q9ULR0 594.651 3 3.6 35.8 0.0022 Q96ST2 495.5329 3 −1.1 40.8 3.40E−06 Q96ST2 367.9039 4 1.8 27.4 0.0015 Q9H3R0 821.4007 2 −1.5 37.8 1.40E−06 Q9H3R0 695.6855 3 3.5 47 1.90E−06 O60271 596.8115 2 −4.4 42.8 0.047 O60271 706.6559 3 4.1 46.4 3.10E−08 O60271 701.3263 3 7 64.2 2.30E−08 O60271 780.0608 3 −5.7 35.4 0.035 Q96N16 623.3181 2 2.7 36.2 0.0012 Q96N16 713.8268 2 −12 34.1 1.30E−04 Q8N9B5 657.3692 2 −0.032 35.9 1.10E−04 Q8N9B5 724.3729 3 −6.9 55.5 8.50E−09 Q9H5J8 466.25 3 13 31.1 0.0022 Q96MG2 865.3917 3 7 52.6 1.80E−05 P53990 565.7727 2 1.5 25.2 0.04 P53990 420.2057 3 −23 29.6 0.097 Q92628 502.7451 2 −0.04 23.9 0.035 Q5JSZ5 825.9764 2 −0.66 25.7 3.50E−04 Q5JSZ5 416.8733 3 −5.2 29.4 0.0034 Q6ZNE5 804.3995 2 0.31 29.9 7.30E−05 Q6ZNE5 632.7896 2 −0.53 57.2 8.80E−04 Q9P266 772.3801 3 −1.3 43.4 1.10E−05 Q9P1Y5 1094.9782 2 0.65 37.3 1.80E−07 Q9HCE5 501.2751 3 9.2 57.5 1.90E−04 Q9HCE5 551.0467 4 6 50.3 2.00E−07 Q9HCE5 569.8155 2 12 34.1 0.009 Q8IXQ4 742.8841 2 2.5 49.2 1.00E−04 Q8N163 965.44 2 0.78 51.8 9.40E−06 Q8N163 771.413 3 3 42.2 3.30E−04 Q8N163 544.0272 4 −12 24.2 0.0032 Q07666 1009.0557 2 −14 51 2.30E−08 P46013 456.7362 4 −3.1 45.5 3.00E−06 P46013 471.2396 3 −1.6 39.3 4.40E−04 P46013 497.7349 4 −2 33.8 5.00E−04 Q9NS87 640.3066 2 20 36.9 0.0064 Q8N5S9 482.235 2 10 25.9 0.037 Q9Y4X4 669.6589 3 −9.8 48.2 8.50E−05 P14618 813.389 3 −6.8 33.9 5.90E−04 P14618 719.3419 2 3.7 24.7 5.20E−04 P30613 Q8N9T8 365.2104 3 15 22.8 0.0065 Q13601 433.882 3 −4.2 36.2 0.0065 Q13601 478.4787 4 −5.2 41.7 3.70E−06 O75676 446.5743 3 12 37.8 4.00E−04 P13010 567.3097 2 −10 36.9 0.0011 P13010 657.839 2 7.5 33.5 2.40E−05 P13010 406.8455 3 −14 31.1 1.00E−03 Q14657 625.3109 3 −6.5 53.5 5.80E−07 P07942 603.2805 3 −4.7 27.7 0.074 P42166 563.9676 3 2.1 27.5 0.0043 P42166 763.7119 3 −0.39 28.9 7.80E−04 Q14160 711.3793 3 −18 43.8 5.20E−06 Q14160 462.2459 3 12 34.1 0.022 Q14160 600.0339 4 −5.6 44.1 7.30E−09 Q6PKG0 561.9504 3 −7.3 49.7 3.50E−04 Q6PKG0 619.6416 3 5.6 53.1 3.60E−05 Q71RC2 744.3937 3 −0.062 49.5 1.40E−06 Q92615 1019.1531 3 −0.13 24.9 0.029 O43561 1020.0438 2 1.7 22.7 4.00E−04 Q9UIQ6 627.3172 4 7.4 40.6 6.90E−06 Q8N3X6 541.7993 2 17 27 0.011 Q96JN0 Q9UHB6 810.1002 3 −3.4 40.6 3.00E−06 Q96GY3 662.349 2 −5.2 40.5 0.05 Q9NUP9 562.7991 2 29 28.8 0.066 Q13136 1005.9911 2 1.1 38.3 2.30E−07 Q13136 1084.037 2 −3.2 39.1 1.10E−06 Q8ND30 1023.8431 3 −0.77 26.9 0.0098 P20700 572.3392 2 −1.8 26 3.60E−05 Q8WWI1 728.8589 2 −12 52.3 0.0013 Q8IWU2 622.8452 2 −1.1 39.6 3.30E−04 Q9C0E8 617.0009 3 9.8 35.9 4.70E−04 Q93052 763.8397 2 9.2 22.5 1.40E−04 Q93052 755.8336 2 −2.1 27.4 8.00E−05 P50851 761.3326 2 −1.3 31.9 9.80E−07 P50851 851.8504 2 −2.2 51.5 9.90E−09 P50851 639.3044 3 15 61 4.10E−05 P50851 633.9662 3 4.5 49.5 9.80E−05 Q8N1G4 945.4597 2 −6.2 46.9 2.80E−06 Q8N1G4 796.4119 4 −2.2 59 2.90E−10 Q9Y2L9 655.8126 2 −1.4 26.2 8.30E−05 Q9Y2L9 513.2605 3 5.9 29.5 6.80E−04 Q5VUJ6 395.7015 4 −11 39.7 7.80E−05 Q96II8 474.2556 2 14 36.1 0.013 O75427 413.8601 3 4.7 27.9 0.0014 Q12912 738.9125 2 −8.9 48.2 0.0057 Q32MZ4 1070.7324 4 0.24 32.4 4.30E−04 Q9Y608 1281.3087 3 −2.3 30.6 0.0028 P83369 520.261 2 −1.8 22.6 7.10E−04 P62310 985.5148 2 1.7 26.1 7.90E−04 P33241 590.7599 2 6.2 35.6 0.025 Q96GA3 537.006 4 −2 22.3 0.035 Q86UE4 717.348 2 −1.4 38 9.00E−06 O60664 742.8439 2 −22 44.9 9.60E−06 O60664 769.0493 3 1.2 60 1.60E−08 O60664 583.3055 2 6.7 47.7 0.063 Q3KQU3 1073.2181 3 −3.9 30.4 0.0011 Q3KQU3 1067.8871 3 −3.3 28.9 0.005 Q9UPN3 829.739 3 −8 46.7 1.70E−06 Q9UPN3 699.8616 4 −1 30.7 7.80E−04 Q96PK2 Q9UPN3 838.0933 3 −1 33 8.60E−05 Q96PK2 Q9UPN3 611.2847 4 −4.7 50.5 1.10E−08 Q96PK2 Q9UPN3 817.9101 2 −4.8 34.2 2.90E−05 Q96PK2 Q9UPN3 639.8107 2 −0.49 37.5 1.90E−06 Q96PK2 Q9UPN3 605.9573 3 −0.38 49.3 1.50E−06 Q96PK2 Q9UPN3 730.334 2 5.9 41 6.30E−04 Q96PK2 Q8WXG6 657.3757 2 −13 34.7 0.0096 Q9Y5V3 714.665 3 5.1 59.6 1.10E−06 Q96MG7 701.316 2 −2.3 48.5 2.70E−04 Q96MG7 969.7688 3 −12 52.3 1.20E−07 P23368 608.0444 3 15 33.6 2.00E−04 P78559 1157.6109 2 9.5 38.8 1.40E−06 P78559 916.7866 3 −14 53.3 1.60E−06 P78559 719.8776 4 3.4 52.3 6.50E−08 P27816 792.4116 2 −0.25 28.1 4.50E−04 P27816 580.6472 3 5.6 51.1 7.80E−06 P27816 497.9203 3 −5.6 25.8 0.028 P27816 843.7541 3 −1.2 47.2 4.40E−05 P27816 730.7259 3 −0.99 45 8.80E−05 P27816 727.8715 2 −3.9 42 0.0061 Q49MG5 502.7553 2 −4.7 30.1 0.041 Q15691 547.2662 3 7.8 26.6 0.0011 Q9P0L2 507.587 3 5.5 38.4 1.60E−04 P43243 1065.4672 2 0.62 38.4 7.70E−09 P43243 622.8264 2 −2.2 36.2 1.30E−06 P43243 686.8753 2 0.15 36.4 3.30E−06 P43243 583.7786 4 −1.2 39.6 2.10E−05 P43243 600.0053 3 6.5 41.5 1.20E−05 P43243 456.7237 2 −2.3 25.6 0.018 P43243 524.2863 4 42 54.5 3.80E−07 Q7Z434 401.8584 3 −22 30.1 0.0099 Q7Z434 333.6772 4 4.1 28.2 0.031 P61244 515.2815 2 −1.7 27.2 0.072 Q9BQG0 726.3666 3 −7.6 44.5 6.80E−06 P49736 837.0505 3 −8.2 35.4 2.70E−05 P49736 645.802 2 −2.1 28.9 0.014 P25205 927.726 3 4.5 45.9 9.50E−08 P33991 586.9691 3 3.3 48 3.90E−07 P33992 541.2561 3 −1.6 53 6.00E−07 P33992 829.8377 2 −22 48.5 2.30E−07 Q14566 445.9049 3 −0.98 38.8 0.0012 Q14566 587.765 2 −13 32 0.0024 Q14676 1192.6804 4 5.2 25.9 3.50E−04 Q14676 935.8055 3 −7.9 30.8 0.0041 Q9NU22 939.4534 3 7.9 45.5 7.80E−07 O60244 728.3893 3 1.7 49.9 1.40E−04 Q15648 586.3193 2 −3.7 39 0.038 Q15648 547.283 3 1.2 36.1 4.80E−04 O95402 487.5985 3 −3.2 51.1 3.20E−04 Q06413 474.5466 3 5.2 32.5 8.80E−04 Q06413 435.9476 4 −7.9 33.2 3.70E−06 P31153 803.4165 2 1.7 25.7 0.001 Q6ZN04 1048.8488 3 −9.3 26.4 3.70E−04 Q8IWI9 1088.4852 2 −0.27 31.4 1.00E−06 Q8IWI9 578.8284 2 −6.6 36.8 0.018 Q8IWI9 1041.8352 3 −7.7 33 2.50E−04 Q8IWI9 502.26 3 3.5 57 2.80E−05 Q5JRA6 525.2844 2 −1.1 33.7 3.90E−04 Q8N108 454.5474 3 9.1 31.6 9.90E−05 Q96T58 499.6148 3 5.4 40.8 9.70E−05 Q96T58 668.6869 3 3.2 51.5 3.20E−05 Q96T58 626.3152 2 1.3 44 8.50E−04 Q8NDC0 400.5423 3 5.7 27.1 0.0033 Q969V6 1230.1066 2 −4.2 24.9 1.30E−05 Q9ULH7 840.3932 3 4.7 51.4 1.70E−07 O14686 660.3398 2 −4.1 34.5 1.40E−04 O14686 820.7642 3 −1.1 36.3 1.00E−04 Q8NEZ4 712.8812 2 1.3 46.4 0.019 Q9Y3A3 638.0062 3 6.2 53.9 5.60E−06 P26038 732.3907 3 7.2 25.9 0.0026 Q14149 736.3953 2 0.61 24.1 0.0051 Q14149 720.8905 2 0.28 41.8 0.0015 P53985 431.5621 3 −9.8 26.8 0.0017 Q02750 415.5408 3 −24 28.8 0.0062 Q02750 709.685 3 9.6 47.9 7.20E−07 Q02750 752.3787 3 2.9 46.7 2.00E−06 O00566 466.2746 3 3.3 34.2 6.70E−04 O00566 652.8626 2 6.3 41.4 0.022 Q99549 844.3957 3 −0.76 35.4 1.40E−05 Q99549 1028.7731 3 −14 23.6 3.10E−04 Q99549 794.3193 2 −1.6 55.5 3.40E−05 P49006 725.8746 2 −8.1 40.6 4.00E−04 Q8NHP6 602.8095 4 −16 37.8 9.40E−06 Q86U44 709.7824 2 0.83 53.3 6.20E−06 P35580 792.055 3 −9.6 25 0.018 P35580 634.3247 2 11 29.9 0.054 P35749 642.3197 2 7.4 27.1 0.043 P35579 521.604 3 8.5 45.1 2.10E−04 P35579 627.3053 2 −6.9 36.9 0.0022 Q13459 557.99 3 1.5 34 0.0017 O14974 627.3053 4 −6.9 42.9 2.90E−06 O75113 688.861 2 6.6 36.9 2.00E−04 Q13765 858.0908 3 −6.1 49.1 2.10E−06 Q13765 924.4515 3 −24 31.4 0.0042 Q9BWU0 472.7181 2 7.8 26.2 2.10E−04 Q9BWU0 464.7216 2 10 28.1 0.0046 Q9BWU0 563.2347 2 2.6 41.1 0.0018 A2RRP1 938.4413 2 −5.6 36.5 5.80E−05 A2RRP1 569.2801 4 −12 39.5 5.10E−06 Q69YI7 863.7732 3 −5.9 50.7 1.30E−04 Q9UHQ1 726.8673 2 −4.8 23.9 0.001 Q9UHQ1 591.296 3 −0.82 40.2 4.80E−04 P49321 679.5959 4 1.8 38.5 3.00E−06 P49321 523.927 3 1.4 47.7 0.0015 P49321 425.2185 4 −4.2 39.9 6.30E−05 P16333 817.8674 2 −1 41.4 3.50E−07 Q9Y6Q9 560.5436 4 4.2 35.2 4.00E−05 Q9HCD5 456.2735 2 9.8 25.8 0.018 Q9HCD5 492.2351 3 −8.6 42.4 6.70E−05 Q14686 663.6483 3 −13 34.3 0.0096 O75376 630.8125 2 −6 44.6 1.20E−04 O75376 549.9297 3 −0.67 53 5.80E−05 O75376 596.9484 3 −2.8 54.4 1.60E−05 O75376 721.3387 2 5 30.6 2.60E−04 O75376 699.316 2 4.8 35.5 0.015 O75376 636.2653 2 −12 32.1 0.0085 Q9Y618 616.3077 2 −6.8 39.8 0.0015 Q9Y618 903.9988 2 11 42.7 1.70E−05 Q92597 459.2619 3 −8.7 43.3 0.0064 Q96SB3 889.4941 2 0.17 30.7 8.60E−06 Q96PU5 635.6574 3 −1.9 45.6 2.10E−04 Q8NHV4 832.9363 2 −8.5 38.2 0.0049 P46934 848.4097 3 1.9 26.7 0.016 Q96PY6 684.826 4 −9.1 33.7 0.0076 P51957 580.2952 2 −2 33.9 7.50E−04 Q8TD19 770.9013 2 3.9 44.2 0.045 Q9H3P2 561.8099 2 −2.6 24.4 7.20E−05 O95644 491.7674 2 −4.2 37.3 0.0064 Q13469 747.0483 3 −4 48.9 1.00E−05 Q00653 675.3181 2 2.1 25.5 0.0063 Q6P4R8 413.7458 2 7.4 25.7 0.038 Q6P4R8 537.7532 4 −2.4 47.4 3.00E−07 O14745 454.7748 2 12 39.5 0.0026 Q86WB0 549.7813 2 −2.3 33.1 0.0039 Q86WB0 741.0469 3 0.66 46.8 1.20E−05 Q6KC79 428.9177 3 9 39.1 0.012 Q6KC79 493.2756 4 7 24.9 0.004 P30414 530.8812 3 13 24.9 0.002 P46087 492.2631 2 −8.1 26.2 0.045 P46087 1155.5475 3 −10 52.3 5.30E−08 P46087 1150.2057 3 −19 48.5 7.50E−08 P46087 794.62 5 20 38 1.60E−05 Q9Y2X3 594.3311 2 11 29.8 0.02 P78316 435.8993 3 −5.7 33.9 0.011 P78316 438.8914 3 21 30.9 0.019 P55209 858.9613 2 −0.83 44.8 3.60E−07 P55209 550.5661 4 −3.2 31.1 3.30E−04 P55209 475.2504 3 8.3 22.8 0.0092 Q99733 572.7957 2 −0.29 37.8 4.10E−06 Q99733 630.3146 3 2.4 56.1 1.00E−08 Q99733 813.918 4 33 32 1.10E−04 Q99733 809.8793 4 −16 53.4 2.20E−09 Q99733 644.9927 3 −3.5 46.4 1.80E−06 Q49A26 556.9489 3 −7 35.5 0.0015 Q14207 458.7825 2 13 25.1 0.046 P06748 762.0246 3 −15 35.4 2.40E−05 P06748 873.0628 3 −6.9 28.7 0.004 Q9Y6Y0 702.3287 3 −10 43.8 9.70E−07 P82970 628.3083 2 −5.7 46.2 7.40E−04 Q08J23 763.1407 4 −4 36.7 1.40E−05 Q08J23 636.3339 5 −2.5 27.9 0.002 Q08J23 492.2567 2 8.5 24.8 0.0075 Q08J23 371.2087 3 17 24.1 0.013 Q08J23 1021.5092 2 8.1 22.2 3.20E−04 P49790 530.278 2 −9 25.6 0.033 P80303 862.9316 2 −11 32.8 6.60E−04 P80303 684.3105 2 1.7 26.6 0.013 Q9H1E3 418.7163 2 12 23.2 0.08 P19338 721.4094 2 −3.3 25.2 3.20E−04 Q8IVD9 456.2354 2 5.9 26.6 0.034 Q8IVD9 857.4669 2 −0.98 39.5 3.10E−06 Q8IVD9 519.9218 3 7.6 40 2.80E−05 Q7Z417 635.6724 3 1.5 32.9 1.80E−04 Q14980 784.3966 2 −14 40.5 0.0049 Q14980 927.2416 4 −11 29.4 0.001 Q14980 602.7781 2 −8.6 41.7 5.10E−05 Q8NFH3 567.9402 3 2.8 38 8.00E−05 Q9UKX7 639.3153 4 0.62 43.6 5.20E−06 Q8N1F7 739.3486 3 7.6 38.8 1.10E−05 P11177 621.2949 3 5.7 33.6 0.0033 O75665 701.6811 3 −10 36.1 0.011 Q8WV07 495.2563 2 −3.1 27.2 0.028 Q9BZF1 557.611 3 12 33.7 0.0014 Q8N6M0 700.7099 3 3.3 57.1 8.30E−06 Q01804 740.3386 3 −6.1 28.2 4.80E−04 Q8N573 698.8929 2 −0.63 28.6 0.001 Q8N573 435.566 3 −0.84 33.3 6.20E−04 Q6IN85 619.801 2 3.8 40.8 0.0034 Q8WXI9 541.2675 2 0.45 42.8 0.0029 P47712 652.8033 2 −9.5 35.2 5.30E−05 Q86U42 685.3593 2 −7 39.5 0.0063 Q86U42 532.9647 3 13 55 3.60E−05 Q8NC51 432.2047 3 28 22.1 0.044 Q13153 882.9118 2 −12 49.2 1.60E−05 Q13177 Q13177 622.8325 2 −4.6 39.4 4.70E−06 Q8WX93 840.421 2 1.8 34.5 0.01 Q86W56 740.3677 3 7.7 28.4 5.70E−04 P09874 401.7048 2 −35 25.7 0.035 P09874 465.7711 2 10 33.5 0.017 P09874 353.5514 3 18 24.1 0.0076 P09874 586.9405 3 −0.65 28.2 0.044 Q96IZ0 361.2023 4 8 28.4 0.0021 P49023 467.7274 2 6.9 31.8 0.012 P49023 612.6551 3 6.6 46.8 6.20E−06 P49023 771.8785 2 1.9 42.3 8.30E−04 Q86U86 490.2353 3 −0.87 26.6 0.045 Q15365 1223.6101 3 −5.1 30.1 0.0016 Q15365 643.0097 3 −7.1 53.5 4.40E−08 Q15365 887.1171 3 −5.2 49.4 2.30E−06 Q15366 906.4588 3 2.1 49.9 3.90E−06 O94913 1111.7555 4 −7.2 22.1 0.0019 Q15154 563.6162 3 −2.6 46.3 3.40E−05 Q15154 764.7111 3 3.7 44 4.90E−06 O95613 1011.4802 3 8.1 34.6 0.0018 Q9BY77 748.8864 2 −5.9 45.5 8.00E−04 O00151 893.912 2 1.7 29.3 3.20E−04 Q6P996 700.8916 2 1.1 41.4 6.70E−04 Q13951 714.2997 2 −0.56 33.9 3.80E−07 O94921 568.9773 3 7.1 43.1 6.10E−04 P00558 501.7499 2 0.087 24.7 0.018 P00558 918.1347 3 −8.1 28.2 9.60E−04 P00558 490.5819 3 2.8 44.4 8.50E−06 P00558 686.3663 3 −7.1 40.4 2.80E−05 P00558 478.9172 3 17 24.9 0.0089 P07205 Q8IZ21 726.8483 2 2.8 32.1 5.70E−04 Q92576 838.9101 2 6.4 27.5 1.60E−04 Q92576 454.8939 3 18 39.9 1.50E−06 Q92576 941.1218 3 3.4 41.1 1.20E−04 Q92576 530.9376 3 1.9 43.8 1.40E−04 Q6NYC8 442.2755 2 8.7 28.1 0.012 Q9UBF8 766.7201 3 −6.7 53.9 2.10E−07 Q9UBF8 614.3193 4 −2.9 24.9 0.0093 O75925 585.6803 3 5.7 45.4 2.20E−06 Q13492 515.9336 3 −2.8 44 4.50E−04 O00562 1007.4763 2 −15 52.1 3.40E−06 O43164 659.8461 2 −3 29.6 0.0021 Q9ULL1 921.9333 2 0.13 25.2 0.0011 Q99569 505.3024 2 −6.4 32.2 3.60E−05 P19174 589.7828 2 9.1 32.8 0.039 Q9UL45 1347.968 3 −15 29.9 1.50E−04 Q7Z3K3 670.3166 2 −8.7 30.9 5.30E−04 Q9Y244 747.3844 3 −7.6 48.5 5.30E−07 Q96QC0 620.3147 3 0.11 48.1 1.80E−05 Q96QC0 658.8625 2 −2.5 46.5 0.015 Q96QC0 938.4655 3 −4.8 41.7 1.10E−04 Q8TF05 704.3491 3 −0.9 24.2 0.0029 P62937 556.3095 2 1 22.2 0.0042 Q8WUA2 857.9648 2 1.6 29.7 1.50E−04 O95685 442.2522 2 −2.9 31 0.033 O75400 541.7818 2 8.1 46.6 0.011 P57071 1206.6293 2 0.34 25 0.0053 P57071 684.3572 4 −6.9 44.8 4.20E−06 P78527 840.0617 3 −0.86 25 5.70E−04 P07737 667.6942 3 −6.2 28.8 0.0037 P07737 528.2513 2 12 26 0.025 P07737 520.2524 2 9.5 34.9 9.30E−04 P07737 854.7551 3 −5.8 36.1 1.00E−04 O60508 443.2527 2 −6.7 22.9 0.0035 O60508 572.0596 4 8.1 39 5.20E−05 O60508 563.2973 2 13 23.6 0.0096 O60508 465.5632 3 −3.3 36.4 0.0026 O60508 574.2879 4 −4.3 47.2 1.20E−07 Q8WWY3 573.9644 3 5 35.1 5.40E−06 Q9ULL5 537.7743 2 −1.3 23.6 0.016 P79522 849.7758 3 8.5 33.3 0.0019 P62333 365.8465 3 2.9 25.1 0.0038 P17980 465.2692 2 0.96 29.6 0.017 P17980 678.3531 3 −6.7 52 9.60E−07 P17980 673.0301 3 6.2 53.9 2.30E−06 P17980 634.8181 2 1.5 22.6 0.04 P43686 635.799 2 −12 53.2 6.90E−04 P62195 654.986 3 −2 46.3 5.70E−06 P28066 533.939 3 2.7 34 7.20E−04 Q8TAA3 623.6471 3 4.8 49.9 4.00E−04 O14818 P20618 532.788 2 −4.5 25.5 9.40E−04 P28070 754.3484 2 0.66 45.6 0.0018 Q99436 493.7846 2 −1 22.2 0.0037 O00232 595.2774 2 −0.74 38.2 0.0087 Q8NDX1 651.809 2 0.028 41.6 0.003 Q8NDX1 418.2104 4 −5.7 39.9 8.30E−06 O75475 580.7258 5 4.6 43.8 5.00E−07 O75475 387.8818 3 3.9 31.4 0.0051 O75475 626.3578 2 11 49.6 0.037 P61289 468.2449 2 −0.75 28.2 0.03 P26599 577.8366 2 −10 41.2 5.60E−04 P26599 437.604 3 14 39.6 9.10E−06 P26599 785.8742 2 3.8 47.7 1.20E−06 P26599 777.8724 2 −1.8 44 0.0012 P26599 777.8709 2 −3.7 45.2 9.70E−05 P26599 769.871 2 −6.9 49.1 3.10E−05 P26599 505.2334 2 −10 24.6 0.034 Q14761 923.0806 3 −11 37.9 1.10E−05 Q14761 1108.5143 3 2.7 35.1 5.60E−05 Q14761 1063.8215 3 −0.022 37.9 6.80E−06 P06454 654.3372 2 −1.4 41 2.30E−07 P06454 832.4412 2 0.093 35.2 5.90E−05 P06454 476.2544 2 2.2 29.9 0.006 P06454 782.9235 2 −2 27.6 0.0033 P26045 564.9375 3 0.22 47.9 6.10E−05 P22102 834.7403 3 −2 57.7 1.80E−06 P22102 430.2471 4 29 24.1 0.0091 P22102 591.8156 2 4.3 46 0.0065 P22234 636.3664 2 −17 29.6 0.0031 P22234 436.2483 3 −4.7 24.9 0.066 P31939 945.0053 2 −12 29.8 0.041 Q96PZ0 765.7245 3 3.7 43.9 3.50E−04 Q96PZ0 441.9001 3 5.1 39.5 9.40E−04 Q96N64 876.7814 3 −4.6 47.6 5.80E−06 P27708 974.7468 4 −9.9 27.6 0.013 Q96PU8 716.3922 2 −4.9 53.5 0.0016 Q5TB80 531.7871 4 −1.5 53.9 1.80E−07 Q2KHR3 524.2761 2 −2 25.2 0.023 Q9Y2K2 1107.0348 2 2.5 34.5 2.90E−06 Q15032 679.3418 3 9.9 38.5 1.60E−06 Q15032 673.9918 3 −17 37.4 2.70E−05 P0C7M2 557.8447 2 −0.74 23.6 0.0054 Q32P51 P09651 P0C7M2 481.9217 3 −14 29.8 0.032 Q32P51 P09651 P0C7M2 503.2672 3 −2.6 29.9 0.0038 P09651 P0C7M2 646.0898 4 2.7 28.8 0.0037 P09651 P0C7M2 422.9679 4 12 31.8 7.60E−05 P09651 O60216 1319.9436 3 −27 24.4 4.60E−04 O60216 1439.373 3 −0.97 28.2 0.0025 O60216 1434.0475 3 3.3 28 0.0022 O60216 681.8575 2 −3.5 24.1 5.80E−04 Q96JH8 745.3844 2 2.4 30.1 2.90E−06 Q96JH8 539.2765 4 −1.5 36.6 5.10E−05 P43487 636.9929 3 6.2 39 4.60E−05 Q15042 791.9123 2 3.9 47.8 6.20E−04 Q09028 456.7423 4 1.9 25.9 0.0013 Q16576 Q7Z6E9 1041.1916 3 2.9 28.1 9.90E−04 Q7Z6E9 593.3615 2 18 30.4 0.004 Q7Z6E9 692.8444 2 8.1 28.4 6.30E−06 Q7Z6E9 559.9359 3 −8.7 34.1 8.10E−05 Q16576 779.3788 2 −2.5 29.2 8.90E−06 Q16576 573.9941 4 −12 29.6 9.80E−05 Q99708 964.4301 2 −12 28.1 3.80E−05 Q96T37 583.2963 2 13 45.6 5.30E−05 Q9UPN6 739.8526 2 −2 30.8 5.50E−05 Q9UPN6 460.2171 3 1.5 32.4 0.0019 P49756 716.9792 3 −5.8 59.2 5.80E−07 Q5T8P6 719.011 3 −2.4 33.5 4.00E−04 Q5T8P6 713.675 3 −8.5 38.4 4.90E−05 Q5T8P6 713.8652 2 −2.1 22.3 7.60E−04 Q5T8P6 705.869 2 −0.17 22.7 2.80E−04 Q9P2N5 760.8699 2 −0.91 35.9 2.70E−07 Q9NW13 984.907 2 −6.3 50.6 3.80E−07 Q96EV2 517.2424 3 −3.6 38.6 2.90E−04 Q14498 849.8904 2 −4.9 43.8 5.00E−07 Q14498 890.7576 3 −10 45.9 2.00E−06 Q9Y5S9 601.5095 4 5.1 43.7 4.50E−08 Q9Y5S9 726.0813 4 −5.9 28.1 0.0057 Q9Y5S9 597.5048 4 −4.9 47.7 3.70E−10 Q9Y5S9 526.4485 5 9.6 30.6 9.60E−04 Q9Y5S9 962.4462 3 −0.58 40.9 5.80E−06 Q9Y5S9 749.8414 2 −0.93 28.1 4.30E−04 O43251 937.9043 2 0.75 46.3 3.90E−05 P49792 869.4243 2 1.4 43 4.10E−07 P49792 606.2963 5 6.3 39.5 1.30E−04 P49792 764.3483 3 −6.9 27.7 0.006 P49792 453.7201 2 −3 23.4 0.017 P49792 681.5493 4 −3.7 34 1.70E−05 P49792 1157.9086 3 −9.2 26.7 0.0099 Q68DN6 A6NKT7 Q7Z3J3 Q99666 Q53T03 O14715 P49792 984.5243 2 −4.8 33.2 2.80E−06 A6NKT7 Q7Z3J3 Q99666 Q53T03 O14715 Q92804 566.5941 3 3 47.2 1.90E−06 P25800 661.3486 2 5.9 24.1 0.016 A6NDE4 758.0301 3 −3.6 22.7 0.032 Q15415 Q15378 P06400 666.792 2 −23 35.8 9.80E−04 P53805 632.3271 3 2.6 43.1 8.80E−06 Q9P258 397.1981 2 6.2 22.4 0.013 Q9P258 317.1538 3 −40 30.6 0.014 Q14257 808.9093 2 9.8 34.2 1.30E−06 Q8IZ40 508.2666 3 3.8 39.4 0.0019 Q8IZ40 774.3639 2 3 55.4 5.30E−07 Q8IZ40 568.6037 3 −12 28.5 0.0019 Q8IZ40 766.3689 2 6.2 40.2 3.10E−05 P54727 523.7205 2 −4.6 28.4 8.70E−04 Q13123 818.3831 3 −4.8 50.8 1.70E−06 Q13123 523.2591 2 −8.7 22.9 0.011 Q13123 467.2408 3 −9.9 36.2 7.00E−04 Q04864 717.3198 2 −0.66 35.5 3.10E−06 Q92900 740.0423 3 6.1 62.6 3.80E−07 Q96D71 861.908 2 −12 51.2 6.10E−07 Q96D71 690.0421 3 −3.3 48.9 3.90E−07 Q96D71 828.6982 3 0.13 59 8.00E−08 Q92785 591.3139 2 −5.7 33.4 0.0012 Q92785 598.317 2 −4.2 35.6 0.0012 Q13127 476.2368 2 2.6 25.4 0.037 P35251 691.3596 3 −7.9 39.5 2.00E−06 P35251 467.708 2 4.3 35.5 0.003 P35251 686.0367 3 4.9 47.4 4.90E−05 P35251 632.7869 2 −23 37.7 0.036 Q2KHR2 556.6503 3 2.2 29.9 0.0067 Q9H0H5 638.3082 2 −1.5 48.5 3.30E−04 Q9H0H5 728.8242 2 −5 33.2 6.60E−04 Q68DN6 856.4174 2 2.5 40.1 1.30E−07 P0C839 A6NKT7 Q7Z3J3 Q99666 Q53T03 O14715 O43665 452.2108 3 −4.1 29.8 0.0036 O43665 519.5628 3 −5.4 44.2 4.60E−05 P98171 698.8462 2 −7.4 37 4.00E−04 P98171 1136.0371 2 −2.9 33.7 1.40E−06 P42331 1154.517 3 2.3 30.6 1.50E−05 P42331 744.0015 3 5.2 44.6 1.90E−04 Q7Z6I6 889.9152 2 3.5 27.4 3.60E−04 Q7Z6I6 1013.5108 4 −3 34 0.001 Q7Z6I6 992.7758 3 −7.1 49.4 4.70E−08 Q6P4F7 935.4164 3 −13 29 0.0057 P61586 640.6616 3 −2.5 42.4 8.10E−04 P08134 Q5UIP0 481.2801 2 −3.7 33.1 0.012 Q5UIP0 680.6394 3 12 46.5 1.30E−05 O95153 838.6621 4 −3.7 23.1 0.049 O95153 529.6074 3 −29 28.4 0.011 Q06587 507.7835 2 1.9 29.4 0.022 Q9BRS2 551.8251 2 −3.4 26.2 0.0026 Q9BRS2 673.3936 2 0.097 25.7 0.0016 Q13546 507.9304 3 15 41.1 1.30E−06 P31350 507.5879 3 −14 38.8 6.40E−05 P18621 830.9908 2 −0.077 36.8 7.20E−07 P46777 891.4249 2 −12 50.6 9.60E−07 P46777 416.2192 3 0.43 31.9 4.20E−04 Q8IYW5 431.8839 3 7 35 3.40E−04 Q63HN8 525.2821 3 −0.97 32.2 0.0011 Q5W0B1 608.942 3 −5.1 22.5 0.031 Q5VTB9 586.2893 3 −0.1 47.2 5.30E−06 Q99942 517.239 2 0.95 24.2 0.017 Q9H777 651.0489 4 −17 23.2 0.008 Q13151 506.5176 4 4.8 47 3.70E−06 Q13151 501.2954 2 9.6 38.6 0.011 Q13151 683.329 3 −1.4 44.2 1.80E−06 Q13151 551.7779 4 6 36.5 1.20E−05 P22626 664.025 3 −2.4 31.1 0.0099 P22626 405.4502 4 2.1 34.1 6.60E−06 P22626 401.447 4 −9 27.1 1.20E−04 P22626 593.2562 2 −4.1 27.7 0.0076 P51991 518.5953 3 −4.8 28.8 0.0016 P51991 675.4156 2 −1.8 26.1 4.70E−04 P51991 557.8444 2 −1.3 27.9 5.20E−04 P51991 434.4605 4 2.3 30.2 2.30E−04 P51991 462.9331 3 7.9 33.6 7.70E−04 Q13464 429.2267 2 −1.7 30.1 0.049 Q9H6T3 378.523 3 −3.6 23.8 0.012 Q9H6T3 926.4674 3 −2.7 55.1 9.90E−08 Q9H6T3 969.1674 3 −0.9 47.6 2.60E−06 P36954 640.8309 2 −6.9 34.8 2.00E−04 P05423 459.2409 3 3 29.9 0.015 Q9NVU0 678.3157 3 1.6 45.8 1.20E−06 Q8TEU7 604.7821 2 −0.54 36 4.80E−05 Q8TEU7 596.7848 2 −0.25 28.9 8.60E−04 Q92766 570.2785 2 −7.2 29.4 0.004 Q8IY81 877.8995 4 −10 33.8 9.60E−06 Q5JTH9 788.8457 4 −3 41.8 8.20E−06 Q5JTH9 788.8351 4 −16 40.1 9.90E−06 Q5JTH9 788.8461 4 −2.4 36.9 1.60E−05 Q5JTH9 1046.1287 3 −1.2 39.1 1.80E−05 Q5JTH9 618.2945 2 −6.8 29.1 3.60E−04 Q14684 769.8537 4 −0.7 25.8 0.004 P60866 446.7393 4 0.93 34.2 2.70E−05 P62266 742.0295 3 1.6 29.7 0.0016 P62266 784.7221 3 −5.8 25.6 0.0015 P62857 655.3537 2 0.21 45.2 0.086 P23396 476.2526 2 8.9 31.4 0.0036 Q96IZ7 549.2897 2 −1.6 35.8 6.80E−04 Q92541 605.2661 3 10 49 4.20E−08 Q92541 785.8209 2 1.2 40.5 3.90E−06 Q92541 599.9287 3 0.35 53 3.20E−08 Q9NQC3 517.2857 2 17 23.3 0.0032 Q9NQC3 682.331 3 −11 47.5 2.20E−05 P09234 744.8917 2 −3 25 7.60E−04 P09234 509.2383 3 −18 38.6 2.00E−05 P09661 632.8091 2 −4.6 34.1 0.0041 Q8IZ73 827.7338 3 −4.9 49.9 1.00E−05 P62306 524.6212 3 −3.1 36.4 0.0019 Q8N1F8 536.6424 3 0.61 24.6 0.029 P55011 558.2956 3 −2.6 34 0.0074 Q96AG3 598.0486 4 12 24.9 0.013 Q9UHR5 572.7506 2 3 36.2 2.10E−05 Q15424 718.303 3 0.43 39.1 2.70E−05 Q15424 389.8636 3 19 28.6 0.002 Q14151 Q15424 876.9452 4 0.7 28.5 0.0017 Q14151 Q15424 670.5357 5 −1.7 50 5.80E−07 Q14151 Q15424 613.7926 4 11 58.9 7.50E−10 Q14151 Q15424 666.8127 2 −5.4 44.1 4.80E−04 Q14151 Q15424 588.7517 2 0.48 45.1 0.0033 Q14151 Q14151 928.9761 2 3.2 38.1 6.10E−06 Q14151 613.7917 2 3.2 40.8 0.0013 Q14151 719.6928 3 −0.31 49 3.40E−06 O43865 551.6385 3 −1.8 51.6 1.20E−06 O43865 1054.9309 2 −16 45.8 3.20E−09 O43865 789.3434 3 −4.7 32.1 1.00E−05 O43865 753.8749 2 −5.6 31.1 0.0013 O43865 611.9803 3 −8.2 44.8 3.90E−06 O43865 745.8807 2 −1.2 42.4 0.006 O43865 621.2629 2 −7.7 30.5 0.012 Q96HN2 458.2483 2 −0.03 31.2 0.052 Q5PRF9 785.7272 3 2.4 41.1 3.70E−04 Q9UPN7 756.6575 4 −6.3 47.1 3.20E−08 P07602 765.863 2 −9.4 40.9 9.10E−06 P07602 663.3343 3 0.84 41.8 2.50E−06 P07602 603.7409 2 −14 38.4 0.0013 O75995 589.2881 2 −3.9 37.5 8.30E−05 O75995 711.7937 2 −41 25.8 0.084 Q01826 1516.7479 3 0.93 42.1 1.70E−07 P43007 605.6328 3 3.2 54.9 2.70E−05 O15027 726.8801 2 −1.7 35.8 1.40E−05 O15027 522.7519 2 0.83 40.2 3.00E−04 O95487 1144.919 3 9.5 24.5 0.023 O14828 638.2995 2 −6.9 28.6 0.027 Q96GD3 773.8944 2 −0.26 29 4.60E−05 O75880 1107.1123 2 4.9 24.4 0.0014 O75880 853.1275 3 −3.2 35.1 1.60E−04 Q9UIL1 637.3021 2 −24 32.7 0.0016 Q9UIL1 510.9325 3 4.6 33.6 0.0063 O60524 553.6177 3 −6.7 36.5 0.0019 P55735 562.584 3 −2.2 32.6 2.10E−04 Q12981 580.9564 3 4.3 26.8 0.046 Q9GZR1 703.6621 3 −5.3 44.2 6.30E−07 Q9UHD8 571.7677 2 −20 27.9 0.018 Q9BYW2 402.236 3 13 30.6 0.0032 Q9BYW2 817.3996 3 1.9 34.7 8.20E−05 Q9BYW2 883.7687 3 −7.5 25.4 0.026 Q7Z333 787.4313 2 0.53 26.6 3.90E−04 Q15637 784.8964 2 −13 47.5 8.40E−06 Q15459 356.8125 3 −28 24.5 9.50E−05 Q15459 351.4769 3 −40 25 1.40E−04 Q15459 719.3953 3 −1.7 40.2 1.30E−04 O75533 941.8958 2 −13 46.5 1.10E−07 Q13435 364.2256 3 14 26.9 0.055 Q13435 898.4512 2 −9 46.4 1.00E−04 Q13435 651.3396 3 −4.1 48.5 5.60E−06 Q15427 618.8253 2 −3 38.6 5.10E−04 P23246 401.2014 4 1.1 30.7 0.0017 Q8IX01 1310.8661 4 1.6 25.4 0.0011 Q8IX01 674.3126 2 0.24 45.5 0.0011 Q8IX01 999.1261 3 −3.4 60.5 3.30E−10 Q99590 835.6921 3 −4.1 58.8 4.90E−07 Q01130 719.8186 2 −0.12 28.1 1.90E−05 Q01130 703.8222 2 −2.2 38.3 1.90E−04 Q01130 545.2738 2 4.2 34.6 0.0051 Q01130 635.7889 2 −2.2 47.8 3.50E−04 P84103 482.7164 2 3 22.2 0.019 Q13243 585.2827 3 −5.1 49.2 9.40E−07 Q13247 498.745 2 8.2 28.6 0.076 Q5FBB7 557.2639 3 4.1 31.6 0.0014 Q8N5H7 526.9266 3 −2.5 40.4 0.0014 A0MZ66 761.8523 2 −0.94 43.8 7.40E−07 Q96FS4 712.3373 2 −9.7 51.2 1.70E−06 Q9UIU6 928.7876 3 5.4 61.4 5.70E−09 P12755 668.3472 3 3.9 44.9 1.10E−05 Q5T5P2 416.5381 3 −1.4 29.2 0.016 Q9BRT9 849.4166 3 −10 49.2 1.20E−05 Q9H2G2 500.2528 3 7.9 28.1 2.90E−04 Q14BN4 843.8928 2 −13 46.8 2.00E−05 O95391 550.3146 2 10 30.9 5.00E−05 O95391 681.6812 3 −6.7 50.8 4.40E−07 O95391 543.5403 4 0.81 35.3 3.30E−05 O95391 742.0353 3 5.1 48.6 2.80E−05 O95347 618.331 3 4.6 44.6 1.30E−06 P51532 609.3476 2 −0.79 22.4 0.01 Q969G3 419.8795 3 1.3 32.5 0.046 A6NHR9 632.291 3 −2.9 53.2 5.80E−10 Q8TAQ2 492.9114 3 −1.3 34.4 0.0015 Q92925 797.8757 2 6.1 42.5 3.40E−04 Q5SXM2 736.887 2 −13 27.7 0.057 Q9UMY4 914.4595 3 2.6 45.9 9.70E−08 Q8TEQ0 859.7477 3 −15 26.2 0.0094 O60749 1009.8868 3 3.2 26.1 0.0095 O60493 599.8294 2 −1.9 27.8 2.20E−04 Q9UNH7 490.7423 2 9.1 28.1 0.0089 Q9UNH7 426.897 3 5.8 35.2 0.031 A7XYQ1 711.8476 2 −9.3 42.9 0.015 P00441 828.7504 3 −1.3 29 0.011 P00441 533.6151 3 −0.76 55 1.10E−05 P18583 1296.6627 3 1 28.2 0.0013 P18583 1096.5876 2 3.7 44.5 8.70E−09 P18583 754.3801 4 −8.9 43 1.10E−06 P18583 803.7332 3 15 34 6.70E−05 P18583 626.9766 3 −6.1 41.9 0.0011 Q9HB58 398.5299 3 14 30 0.0044 Q9HB58 458.8638 3 −13 28.9 0.0014 P08047 1047.0821 2 5.1 44.3 2.80E−06 Q02447 1236.5731 3 4.8 22.3 0.026 Q02447 733.3483 3 −7.7 58.9 3.20E−08 Q86XZ4 788.4009 2 −18 37.1 3.30E−04 Q9UBP0 577.758 2 1.3 39 0.023 A1X283 830.4031 2 −5.8 35.4 1.60E−06 Q5M775 766.3726 2 −2.7 38 9.80E−04 P19623 609.3094 2 −13 44.2 0.0013 O75934 644.9756 3 −0.17 51.8 6.80E−07 O75940 731.3598 2 0.17 33.9 4.90E−06 Q8N0X7 625.3093 2 6.9 22.1 8.50E−04 Q8N0X7 506.7756 4 19 26.3 0.0069 Q8N0X7 538.7899 4 0.5 29.9 0.0016 Q9NUQ6 482.5808 3 −32 27.4 0.059 Q7KZ85 612.3149 2 −3.4 33.8 0.0015 Q13813 872.4677 2 0.34 31.4 1.10E−04 Q13813 486.8061 2 −4.1 23 0.011 O15020 605.312 3 −4.8 45.7 1.50E−04 O15042 910.7951 3 −14 26.2 0.091 O15042 967.4972 2 −32 46.4 1.30E−05 O15042 828.7499 3 0.01 38 2.70E−05 O15042 653.8394 4 2.1 38 1.30E−04 O15042 608.8057 2 −1.1 35.2 1.80E−07 O15042 448.9081 3 6.8 41.1 2.60E−07 O15042 519.029 4 3.9 48.2 7.40E−08 Q6ZRS2 788.3406 3 −5.5 45.7 2.60E−06 Q6ZRS2 848.6655 3 −30 41.6 4.20E−08 P12931 860.4475 2 −2.8 26.5 1.70E−04 Q8NEF9 531.2961 2 1.1 27.9 0.0016 Q8NEF9 478.7739 4 −0.65 22.5 0.085 Q9UHB9 585.5641 4 17 49.3 1.30E−07 Q9UHB9 518.2524 3 12 38.7 0.004 Q96SB4 1439.3376 3 5.3 28 2.60E−04 Q9UQ35 489.739 2 7 28.9 0.0047 Q9UQ35 523.7805 2 −5 36.5 0.0018 Q9UQ35 433.8676 3 −15 22.8 0.078 O60232 639.9947 3 −4.3 55.7 6.90E−06 Q9BWW4 1146.555 2 4.5 22.9 0.0016 Q9NQ55 831.9291 2 −2.9 41 8.60E−08 P28290 769.4176 2 1.3 41.8 0.0041 Q76I76 792.3868 3 −0.59 30.4 0.0021 Q08945 912.4597 2 −2.8 49.6 8.00E−06 Q9ULZ2 640.9686 3 −3.6 55.6 1.60E−05 Q9ULZ2 635.637 3 −3.7 57.2 3.90E−05 O94804 1440.6692 4 1.1 25.8 2.10E−04 Q9Y6E0 919.9206 2 −18 54.6 3.10E−08 Q9Y6E0 609.8011 4 1.4 32.3 0.0096 Q9UEW8 799.3599 2 16 55.5 4.90E−04 Q13043 1230.8882 3 1.3 33.7 2.40E−04 Q13043 962.4368 4 −5.5 22.6 0.025 Q13043 801.4111 5 45 35 8.50E−05 O43815 483.2445 2 1.9 32.5 0.0058 O43815 694.8362 2 −2.9 48.2 9.90E−04 O43815 615.3103 3 −1.1 43.5 4.70E−04 O43815 493.7484 4 −21 28.1 0.0056 O60499 562.9101 3 −1.1 23.4 3.30E−04 O60499 550.2824 2 18 32.8 0.019 Q86Y82 645.6447 3 5.4 62.6 2.30E−06 P56962 585.3108 4 9.3 30.6 1.00E−04 P56962 697.6675 3 −5.2 53.4 8.10E−05 O15400 905.4229 3 −22 66.6 1.80E−08 Q9Y2Z0 920.9676 2 −14 26.6 0.0026 Q96A49 537.5916 3 0.68 43.1 2.60E−04 P07814 702.9106 2 3.1 52.2 0.0046 O95926 567.9626 3 4.7 25.8 0.0053 O95926 619.9912 3 −4.1 51.6 2.40E−07 P41250 716.8691 2 −8.5 52.1 6.30E−05 Q92797 524.2259 2 3.2 31.3 0.0031 O43776 971.4463 2 −0.63 31 8.20E−05 Q8NF91 610.962 3 3.1 50.1 5.70E−07 Q8WXH0 601.2927 2 −2.1 44.7 2.40E−04 P23381 775.8948 2 −1.7 48.5 1.10E−05 Q9NUM4 580.2535 2 −4.4 37.4 3.10E−04 Q9NUM4 572.2618 2 5.6 33.8 0.0046 Q9BVX2 913.4464 3 −20 31.1 0.0016 P29083 605.0193 4 5.4 35.1 1.90E−04 P29083 601.0209 4 5.9 44.9 1.80E−06 P35269 1007.3983 2 1.3 55.5 1.30E−08 P35269 999.4013 2 1.8 52.8 2.30E−07 O75410 669.3194 2 −1.3 24.8 3.40E−05 O75410 635.2991 3 0.77 34.2 3.00E−05 O75410 379.4883 3 −31 22.4 0.0045 O95359 459.5494 3 −2.8 24.8 0.021 Q9Y6A5 921.7929 3 5.9 31.8 3.90E−04 Q9Y6A5 750.3785 2 −2.1 34.1 0.0043 Q96BN2 504.0201 4 1.7 31.8 3.90E−04 Q15544 829.8834 2 −9.7 39.6 3.50E−05 Q15545 1032.492 2 −2 30.2 0.0038 Q71U36 669.1185 5 4.2 56.2 1.60E−08 P68363 Q9BQE3 Q13748 Q6PEY2 Q71U36 665.9205 5 5.7 62.1 1.10E−09 P68363 Q9BQE3 Q13748 Q6PEY2 Q71U36 946.0852 3 −11 51.1 1.30E−08 P68363 Q9BQE3 Q13748 Q6PEY2 Q71U36 492.5025 4 5.7 42.9 6.80E−06 P68363 Q9BQE3 Q13748 Q6PEY2 Q71U36 514.7216 2 0.51 34.3 0.035 P68363 Q9BQE3 Q13748 Q6PEY2 P68366 Q71U36 706.6535 3 −5 27.8 0.0062 P68363 Q9BQE3 Q13748 Q6PEY2 P68366 Q9NY65 Q71U36 744.7286 3 2.4 36.4 9.50E−06 P68363 Q9BQE3 Q13748 Q6PEY2 P68366 Q9NY65 Q13885 334.2091 3 −2.1 22 0.071 Q9BVA1 P68371 Q13509 P07437 Q13885 436.7664 2 6.4 30.8 0.087 Q9BVA1 P68371 Q13509 P07437 P68371 859.4191 5 −15 41.1 1.90E−05 P07437 Q15814 658.03 3 0.2 39.1 4.50E−07 O60343 763.0459 3 −3.5 55.2 3.30E−05 O60343 672.0145 3 −3.1 50.5 4.90E−05 Q9BZK7 586.3129 3 −20 32.1 0.0085 Q9BZK7 691.336 2 −9.6 43.6 0.016 O60907 Q9BZK7 609.805 2 2.2 40.9 0.0013 Q9BQ87 O60907 598.2951 2 −1 39.3 0.032 P23193 603.7908 2 −3.8 27.3 0.0051 Q9UGU0 1006.0216 2 −1.5 48.2 3.60E−09 Q9UGU0 954.2312 4 −2.5 22.6 0.02 Q9UGU0 548.7724 4 −4 32.2 0.0013 Q13428 935.4953 2 −0.91 37 3.50E−07 Q13428 927.4999 2 1.3 37.6 1.50E−07 Q13428 958.0103 2 0.16 32.3 1.80E−06 P50991 904.4691 3 −13 38.6 6.50E−05 P50991 525.2248 2 6.3 34.3 0.002 P50991 517.2261 2 4 31.5 0.017 P48643 872.7516 3 −9.3 36 4.90E−04 P48643 652.3692 3 −6.7 48.5 7.30E−07 P40227 676.3702 3 15 31.4 3.40E−04 P13693 545.2834 2 −1.3 29.7 0.0049 O60522 686.3245 4 7.1 24.2 0.079 Q8IWB9 575.7741 2 −6.8 30.8 0.0014 Q8IWB9 858.9738 2 −7.4 24.2 4.90E−04 Q00403 703.8401 2 7.7 31.8 0.0032 Q00403 695.8365 2 −0.95 37.1 0.029 Q9NZI6 575.849 2 3.2 36.2 0.073 Q12800 Q9NZI7 Q92664 697.7161 3 −0.33 44.4 6.10E−05 Q04206 721.3227 2 −2.5 35.6 4.20E−06 Q96RS0 428.8935 3 9 27.2 0.0093 Q96RS0 720.8799 2 −2 30.9 4.60E−05 Q96RS0 709.9974 3 −2.8 24.1 0.012 Q86V81 715.8326 2 2.3 46.5 4.30E−07 Q13769 440.2166 2 6.1 25.8 0.05 P52888 687.3451 2 −0.95 35.6 3.60E−05 O15164 664.6242 3 −5.5 36.4 1.30E−04 Q13263 1426.8933 3 1.10E−04 38.5 3.70E−08 Q13263 824.3788 2 2.4 42.8 4.30E−09 Q13263 1010.0201 2 −21 37.5 4.00E−04 Q13263 577.788 2 0.019 43.1 0.002 Q13263 456.2436 2 −3.8 23.4 0.061 Q9UNS1 972.4909 2 1.9 35.7 9.10E−06 Q9BSI4 1033.9965 2 −3.2 25.8 1.80E−04 Q9BSI4 1026.0031 2 0.72 41.1 1.30E−05 Q86UE8 934.4821 3 −7.8 22.9 0.044 Q9H0V1 731.0532 3 −2.6 29.4 0.012 Q6ZVM7 402.2346 3 7.9 22.8 0.0059 Q9BVT8 608.9508 3 −9.2 36.5 4.60E−04 Q9BVT8 603.6198 3 −8.2 44 4.50E−04 Q8NFZ5 478.9161 3 7.9 44.1 9.40E−04 Q8NDV7 782.8917 2 −3.4 27.9 7.00E−04 Q8NDV7 620.07 4 8.1 23.2 0.0096 Q96GM8 1008.9917 2 2 42.9 1.30E−07 Q96GM8 762.3608 2 −13 32.7 6.70E−05 Q5JTV8 938.495 2 3.1 37.6 3.00E−07 Q5JTV8 448.9175 3 11 35.3 4.20E−05 Q5JTV8 428.2089 3 −12 34.5 8.60E−04 Q9H0E2 620.6697 3 12 44.5 4.60E−07 O60784 464.7612 2 −6.4 38.2 0.08 O60784 1207.2751 3 −3.6 26 0.0021 O60784 1360.34 3 −3.7 28.4 6.00E−05 O60784 482.5728 3 −12 38.5 6.80E−04 O60784 477.2509 3 8.7 34.5 0.0015 Q02880 738.8719 2 −0.28 41.4 0.0032 Q12888 656.8251 4 −0.49 46 1.30E−06 Q12888 839.9387 4 30 34.3 3.70E−04 Q12888 721.3541 2 −4.2 52.6 0.023 Q12888 507.7201 2 1.9 23.5 0.024 Q12888 667.3603 2 1.7 30.1 0.0082 O43399 721.8639 2 −2 26.3 2.70E−04 Q5T0D9 1006.5086 3 −9.5 32.5 3.30E−04 Q5T0D9 913.2612 5 −16 22 0.07 P12270 1124.0409 2 2.1 33.2 1.30E−05 P12270 629.3242 3 1.3 60.4 5.40E−08 Q9Y2W1 663.6706 3 −3.2 53 4.60E−08 Q15633 672.3055 3 −4.1 48.2 1.30E−07 Q96PN7 763.6944 3 −13 32.8 1.80E−05 Q9UPN9 583.8284 2 −2.8 28.9 4.30E−04 Q9UPN9 815.7195 3 2.2 28.2 0.0058 Q9UPN9 810.3852 3 −1.1 34.6 2.90E−04 Q15650 557.6242 3 −3.3 39.4 6.60E−04 Q15650 848.3895 2 4 45.1 2.00E−04 Q7Z2T5 1096.5593 3 −4.9 54.4 3.00E−10 Q9Y2L5 473.2404 3 12 43.7 0.0099 Q92574 736.869 2 −7.2 42.8 4.60E−04 Q92574 656.089 4 −0.31 26 0.0095 Q92574 827.393 2 −0.13 50 1.50E−04 Q2NL82 604.2764 2 −4.5 39.1 1.10E−06 Q2NL82 560.285 3 0.83 48 3.30E−08 Q2NL82 596.2769 2 −8.1 39.6 3.20E−05 Q2NL82 560.2876 3 5.6 37 1.10E−06 Q2NL82 609.9619 3 −8.5 42.7 8.30E−05 Q99614 661.2932 3 −8 41.5 2.00E−06 O95801 612.3082 2 −3 29.2 1.00E−04 Q9UNY4 711.4294 2 −5 22.4 0.0033 Q9UNY4 517.3247 3 3.9 29 0.0014 P63313 624.2846 2 0.51 41 0.0033 P04818 426.731 2 −3.2 23 0.0056 P25490 1025.0097 4 −13 33.5 3.20E−05 Q13432 429.9161 3 4.5 42.9 2.20E−04 A6NIH7 668.8739 4 0.24 40 2.50E−06 P26368 692.6958 3 −3.2 49.2 1.10E−07 P26368 687.3638 3 −3.7 58.5 4.20E−08 Q3KQV9 1094.0704 2 1.9 43.5 2.00E−08 Q13838 511.2687 2 −1.2 32.2 0.049 P22314 658.6626 3 −0.22 36.1 9.70E−05 Q8TBC4 715.3295 3 0.66 28.7 0.0019 Q8TBC4 758.7929 2 1.8 48.6 7.10E−07 Q5T6F2 759.3829 2 −0.63 22.5 3.60E−04 Q5T6F2 570.7653 2 2.8 30.8 4.90E−06 Q5T6F2 597.2897 2 3 33 0.0015 Q9C0C9 1065.1611 3 −9.6 28.9 7.90E−04 Q9C0C9 1059.8263 3 −13 38.6 1.60E−04 Q9C0C9 880.6616 4 −13 26.6 0.0033 Q9C0C9 1302.6199 3 5.3 30.6 0.0012 Q9C0C9 420.5742 3 7 24.5 7.50E−04 O14562 1090.4749 4 −15 42.2 4.40E−08 Q9NPG3 1143.0427 2 −18 44.7 3.20E−07 Q14694 753.6938 3 −8 31.3 2.60E−04 Q14694 458.2583 2 9.5 38 0.021 Q14694 701.3464 3 −7.4 39.1 3.10E−05 P54578 513.7778 2 1.6 32 0.018 P54578 622.2935 2 −0.35 43.6 3.30E−05 O94966 576.2896 3 2 28.2 0.0018 Q14157 607.8398 2 6.9 22 0.0015 Q14157 791.3962 3 −15 48.8 7.20E−07 Q14157 830.3892 2 −9 31.8 2.80E−04 Q70CQ2 463.2114 2 4 26.1 0.028 Q70CQ2 706.8328 2 5.3 27.7 4.20E−04 Q9P275 540.8051 2 8.6 27.9 0.016 Q9H9J4 445.7561 2 12 37.4 8.80E−04 P45974 625.7867 2 −1.7 45 2.30E−06 P45974 617.7907 2 0.68 30 3.50E−05 P45974 480.615 3 6.2 32.1 1.80E−04 P45974 623.837 2 −9.9 36 0.033 P45974 675.3514 2 0.65 33.6 9.00E−05 Q93009 659.9335 3 −0.98 45.6 2.80E−07 Q93009 720.2814 3 2 50.9 7.00E−07 Q9UMX0 870.4346 2 3.5 29.1 1.30E−04 Q5T4S7 390.8701 3 8.1 35.6 1.60E−05 O94888 540.5906 3 −15 42.6 3.90E−04 O94888 601.534 4 −23 30 6.90E−04 O94888 717.3751 2 11 34.3 1.10E−05 Q16851 692.8494 2 4.3 54.5 0.063 A0JNW5 859.4135 3 −1.4 26.5 0.0025 Q96T88 747.3409 3 −4.2 42 2.50E−06 Q96T88 797.411 4 48 60.3 1.00E−08 Q86UX7 626.3471 2 3.1 42.8 0.011 Q86UX7 443.9826 4 −26 38.1 4.10E−04 Q9NZ43 650.2803 2 0.97 33.5 6.70E−04 Q15853 1464.7474 3 −4.7 35.2 2.50E−05 O60763 567.7412 2 −4.8 25.5 0.0023 P46939 634.8724 2 4.3 25.6 0.0021 P63027 577.2989 3 25 30.6 4.10E−04 Q15836 Q9Y5K8 630.3138 2 −5 31.2 0.0048 P08670 454.2513 2 7.7 27.6 0.019 P08670 639.8444 2 1.1 23.8 2.50E−04 P08670 651.8523 2 −2.9 30.6 1.00E−04 P08670 720.8728 2 0.96 41.1 1.10E−05 P08670 604.6469 3 −1.4 65 9.00E−08 P08670 705.0226 3 −1.3 52.9 4.50E−07 P08670 376.4564 4 5.1 31.5 3.40E−04 P08670 545.6313 3 2.9 37.2 2.90E−05 P08670 502.0231 4 −0.35 27.4 0.0011 P08670 474.2526 3 −25 44 3.20E−04 P08670 448.502 4 5.7 27.1 0.0059 Q5THJ4 679.3378 2 −4.6 31.2 0.018 Q9UN37 588.9353 3 −0.85 47.2 5.10E−04 Q9UN37 640.9725 3 4.7 27.1 0.0062 Q99986 386.86 3 0.44 33.9 0.0011 Q7Z5K2 476.2366 2 10 24.1 0.0055 Q92558 779.7277 3 11 54 1.30E−05 Q9Y6W5 1083.515 4 16 41.1 5.20E−06 Q9Y6W5 633.0053 3 −2.7 45.2 4.30E−05 A8K0Z3 984.5248 4 −17 52.7 2.40E−07 Q9C0J8 435.7081 4 6.3 24.8 0.0035 Q5JSH3 972.0395 2 8.3 37.9 8.50E−06 Q9H6Y2 438.7174 2 3.7 27.6 0.027 O43379 1109.2663 3 −6 37.5 1.50E−05 Q96MX6 912.9972 2 3.2 33 1.10E−06 O76024 496.7763 2 −7.2 31.2 0.0013 O76024 730.6953 3 −1.5 35.3 8.80E−04 O43516 608.3255 4 −3.5 45.9 1.80E−08 Q9H4A3 707.815 4 4.7 34.3 2.70E−05 Q9H4A3 1167.0025 2 −3.4 50.4 3.30E−11 Q9H4A3 563.2531 5 2.4 41 7.00E−07 Q9H4A3 414.6975 4 −5.4 37 3.30E−06 Q9H4A3 932.4238 2 2.5 58 2.30E−06 Q9H4A3 838.7054 3 23 56.8 1.00E−07 Q96S55 622.6505 3 0.23 29.8 0.0039 Q6AWC2 443.279 2 −0.92 25 0.011 P23025 747.3813 3 −12 60 1.40E−07 P46937 682.3796 2 5.7 23.4 6.30E−04 P67809 855.4151 3 3.3 44.5 1.10E−06 P67809 673.8279 4 −10 47.1 1.30E−08 P67809 863.0819 3 −27 48.6 7.20E−08 Q9GZM5 826.8774 2 0.15 32.9 6.80E−05 Q6ZSR9 802.416 2 −14 31.1 4.50E−04 Q6ZSR9 585.8135 2 −9.4 30 0.0073 A8MX80 652.3391 3 0.68 22.5 0.028 Q9H6S0 895.3569 2 −0.24 53.6 4.40E−07 Q9BYJ9 679.841 2 3.5 26.3 9.90E−05 Q9BYJ9 726.6064 4 0.45 22.8 0.024 Q9BYJ9 718.6071 4 −2.2 39.8 9.40E−06 Q9Y5A9 669.3386 4 −8.1 46.5 3.20E−07 Q9Y5A9 682.8468 2 4.3 30 7.20E−05 Q9Y5A9 955.1275 3 −14 62.1 4.20E−09 Q9Y5A9 1012.2638 4 0.3 28.2 0.0086 Q9Y5A9 857.4025 3 −7.4 69.2 6.50E−09 Q7Z739 926.4589 3 −19 48 9.90E−07 Q7Z739 722.8388 2 −0.035 33.7 0.0014 P43403 488.2466 2 −3.6 33.3 7.70E−04 Q8NCN2 730.3552 2 0.59 30.5 2.40E−04 Q8NCP5 839.407 2 −2.6 22.4 1.60E−04 O75152 668.407 2 −2.9 27.7 5.00E−05 O75152 620.8188 4 2.3 40.1 2.20E−06 Q9UPT8 759.8306 2 −8.4 51 2.40E−05 Q9UPT8 674.1222 4 32 35.5 6.20E−05 Q5T200 497.2648 3 −2.2 24.9 0.016 Q5T200 505.5844 3 13 28.2 0.0013 Q6PJT7 1304.925 3 −1.4 27.4 3.80E−04 Q7Z2W4 553.298 2 3.6 30.3 9.60E−05 Q7Z2W4 663.3275 2 −5 45.2 2.00E−04 Q86VM9 741.0172 3 1.5 24.5 0.022 Q9C0B9 620.3225 2 4 46.2 2.10E−05 Q6NZY4 708.8519 2 −0.04 36.9 6.20E−04 P37275 869.06 3 −2.6 44.5 5.20E−07 O43829 785.3593 3 −0.25 51.6 1.90E−07 O43829 851.0337 3 −3.8 57.4 4.40E−08 Q6FIF0 1121.534 3 4.7 28.7 0.0043 Q6FIF0 741.8363 2 −3.6 48.5 4.00E−04 O95159 1104.0579 4 0.9 22.8 0.035 P17010 494.7613 2 2.1 26.2 0.043 P17010 546.9704 3 2.5 26.4 0.003 Q7Z3T8 877.9525 2 −20 47 2.30E−05 Q7Z3T8 804.889 2 1.3 26.5 3.00E−04 Q7Z3T8 568.3072 3 1.5 40.9 4.00E−05 Q14202 1161.5114 3 0.59 28.4 0.0011 Q5VZL5 485.2796 3 5.6 31.4 2.50E−04 P52747 679.3239 3 −1.5 59.9 1.20E−07 P52747 934.1298 3 −9 47.4 1.30E−06 P98182 963.9767 2 −2.9 23.5 0.0016 O43296 589.2808 2 −7.4 38.2 5.50E−05 Q9NRM2 758.3427 2 2.5 25.8 4.70E−05 Q9UL40 741.8506 4 −9.4 31.6 5.30E−04 Q9H582 421.2414 3 16 22.1 0.01 Q9H582 463.9373 3 9.1 39.6 4.60E−05 O15015 930.9646 2 1.8 35.8 4.00E−07 Q6DD87 1035.1812 3 −26 56 5.80E−09 Q96JM3 1185.6155 2 0.71 35.7 1.20E−05 Q96JM3 625.3273 4 −12 44.8 7.50E−05 P17028 651.0446 3 4.2 49.2 1.80E−05 P17028 867.4384 2 −8.6 41.9 0.0017 P36508 782.9207 2 0.71 27.4 1.80E−04 Q9UHR6 833.909 2 −17 45.4 6.50E−04 Q9UHR6 1177.5831 3 −0.27 28.7 0.0058 Q15942 738.3417 2 −12 29.9 9.80E−05 Q15942 730.359 2 8.3 30.9 0.0068 Q15942 572.7885 4 4.1 43.3 1.40E−06 “E value” is the expectation value.

TABLE 3 Caspase-like cleavage sites. P4-P4′ indicates the eight amino acid residues spanning the cleavage site, which is located between the fourth and fifth residues of the sequence. P1 residue indicates the residue directly preceding the cleavage site. P1′ indicates the residue directly following the cleavage site. P1 residue # indicates the residue number in the full-length protein sequence corresponding to the P1 residue. Entries separated by vertical bars indicate cleavage sites found in more than one homologous protein. P1 Swiss-Prot ID Swiss-Prot acc # residue # 2A5G_HUMAN Q13362 14 3MG_HUMAN P29372 36 41_HUMAN P11171 550 4EBP1_HUMAN Q13541 25 4EBP2_HUMAN Q13542 26 AASD1_HUMAN Q9BTE6 80 ABL1_HUMAN P00519 939 ABLM1_HUMAN O14639 567 ACAP3_HUMAN Q96P50 588 ACINU_HUMAN Q9UKV3 68 ACINU_HUMAN Q9UKV3 511 ACINU_HUMAN Q9UKV3 663 ACOC_HUMAN P21399 673 ACSL3_HUMAN O95573 571 ACSL4_HUMAN O60488 562 ACTB_HUMAN P60709 157 ACTG_HUMAN P63261 ACTN1_HUMAN P12814 5 ACTN1_HUMAN P12814 22 ACTN2_HUMAN P35609 29 ACTN3_HUMAN Q08043 36 ACTN4_HUMAN O43707 41 ADDA_HUMAN P35611 633 AEBP2_HUMAN Q6ZN18 233 AEDO_HUMAN Q96SZ5 34 AF1L2_HUMAN Q8N4X5 312 AF1L2_HUMAN Q8N4X5 630 AFTIN_HUMAN Q6ULP2 339 AGGF1_HUMAN Q8N302 148 AHNK_HUMAN Q09666 575 AHNK_HUMAN Q09666 737 AHNK_HUMAN Q09666 739 AHNK_HUMAN Q09666 865 AHNK_HUMAN Q09666 919 AHNK_HUMAN Q09666 1168 AHNK_HUMAN Q09666 1424 AHNK_HUMAN Q09666 1583 AHNK_HUMAN Q09666 2711 AHNK_HUMAN Q09666 2882 AHNK_HUMAN Q09666 3464 AHNK_HUMAN Q09666 3493 AHNK_HUMAN Q09666 3718 AHNK_HUMAN Q09666 4358 AHNK_HUMAN Q09666 5580 AHSA1_HUMAN O95433 18 AHSA1_HUMAN O95433 254 AHTF1_HUMAN Q8WYP5 1367 AIM1_HUMAN Q9Y4K1 67 AKA12_HUMAN Q02952 451 AKAP2_HUMAN Q9Y2D5 472 AKAP9_HUMAN Q99996 1033 AKNA_HUMAN Q7Z591 799 AKP13_HUMAN Q12802 544 AKP13_HUMAN Q12802 829 AKP13_HUMAN Q12802 905 AKP13_HUMAN Q12802 1055 AKP13_HUMAN Q12802 1539 AKP8L_HUMAN Q9ULX6 108 ALMS1_HUMAN Q8TCU4 427 ALMS1_HUMAN Q8TCU4 590 ALMS1_HUMAN Q8TCU4 779 ALO17_HUMAN Q9HCF4 273 AMPD3_HUMAN Q01432 36 AMPM1_HUMAN P53582 12 ANKH1_HUMAN Q8IWZ3 4 ANKH1_HUMAN Q8IWZ3 1048 ANKS6_HUMAN Q68DC2 275 ANS1A_HUMAN Q92625 529 ANXA2_HUMAN P07355 16 AXA2L_HUMAN A6NMY6 AP1G1_HUMAN O43747 689 AP1G2_HUMAN O75843 631 AP2A2_HUMAN O94973 690 AP3B2_HUMAN Q13367 843 APBB2_HUMAN Q92870 279 APC_HUMAN P25054 1498 APMAP_HUMAN Q9HDC9 22 APTX_HUMAN Q7Z2E3 141 AR13B_HUMAN Q3SXY8 241 ARBK1_HUMAN P25098 527 ARBK1_HUMAN P25098 481 ARBK2_HUMAN P35626 ARHG1_HUMAN Q92888 292 ARHG2_HUMAN Q92974 626 ARHGA_HUMAN O15013 1246 ARI1A_HUMAN O14497 75 ARI1A_HUMAN O14497 606 ARI4A_HUMAN P29374 1030 ARI4B_HUMAN Q4LE39 1072 ARID2_HUMAN Q68CP9 625 ARID2_HUMAN Q68CP9 629 ARM10_HUMAN Q8N2F6 86 ARMC6_HUMAN Q6NXE6 82 ARNT_HUMAN P27540 151 ARP2_HUMAN P61160 161 ARP21_HUMAN Q9UBL0 494 ARP3_HUMAN P61158 59 ARPC5_HUMAN O15511 29 ARPC5_HUMAN O15511 32 ARS2_HUMAN Q9BXP5 161 ASB13_HUMAN Q8WXK3 51 ASCC1_HUMAN Q8N9N2 34 ASCC2_HUMAN Q9H1I8 621 ASHWN_HUMAN Q9BVC5 105 ASPP2_HUMAN Q13625 527 ATAD5_HUMAN Q96QE3 284 ATD2B_HUMAN Q9ULI0 77 ATF1_HUMAN P18846 46 ATF4_HUMAN P18848 65 ATF7_HUMAN P17544 43 ATG3_HUMAN Q9NT62 104 ATRX_HUMAN P46100 919 ATX1L_HUMAN P0C7T5 308 ATX2_HUMAN Q99700 842 ATX2L_HUMAN Q8WWM7 584 ATX3_HUMAN P54252 217 AZI1_HUMAN Q9UPN4 548 BA2D1_HUMAN Q9Y520 888 BA2D1_HUMAN Q9Y520 2189 BAP1_HUMAN Q92560 311 BAP31_HUMAN P51572 164 BASP_HUMAN P80723 165 BASP_HUMAN P80723 171 BAT3_HUMAN P46379 1001 BAZ1A_HUMAN Q9NRL2 499 BCAP_HUMAN Q6ZUJ8 148 BCLF1_HUMAN Q9NYF8 324 BCLF1_HUMAN Q9NYF8 382 BCR_HUMAN P11274 243 BDP1_HUMAN A6H8Y1 525 BID_HUMAN P55957 75 BIG3_HUMAN Q5TH69 292 BIN1_HUMAN O00499 301 BIRC6_HUMAN Q9NR09 461 BL1S3_HUMAN Q6QNY0 64 BLNK_HUMAN Q8WV28 177 BNIP2_HUMAN Q12982 83 BPTF_HUMAN Q12830 1625 BRD1_HUMAN O95696 921 BRD4_HUMAN O60885 337 BRD8_HUMAN Q9H0E9 560 BTB14_HUMAN Q96RE7 174 BUB1_HUMAN O43683 395 BUD13_HUMAN Q9BRD0 273 C170L_HUMAN Q96L14 50 C1QBP_HUMAN Q07021 185 C2C2L_HUMAN O14523 442 C2D1A_HUMAN Q6P1N0 30 C2D1B_HUMAN Q5T0F9 460 CA059_HUMAN Q5T8I9 13 CA103_HUMAN Q5T3J3 515 CA163_HUMAN Q96BR5 120 CA165_HUMAN Q7L4P6 103 CA170_HUMAN Q5SV97 42 CA175_HUMAN Q68CQ1 411 CA1L1_HUMAN Q08AD1 421 CABL2_HUMAN Q9BTV7 58 CACO1_HUMAN Q9P1Z2 134 CADH2_HUMAN P19022 799 CAF1A_HUMAN Q13111 110 CAF1A_HUMAN Q13111 614 CALR_HUMAN P27797 121 CALR_HUMAN P27797 258 CALR_HUMAN P27797 328 CAMKV_HUMAN Q8NCB2 407 CAMLG_HUMAN P49069 9 CAMLG_HUMAN P49069 115 CAMP1_HUMAN Q5T5Y3 751 CAMP1_HUMAN Q5T5Y3 1254 CAPR1_HUMAN Q14444 94 CAPZB_HUMAN P47756 149 CASC3_HUMAN O15234 389 CASC5_HUMAN Q8NG31 1194 CASP_HUMAN Q13948 387 CUX1_HUMAN P39880 376 CASP3_HUMAN P42574 28 CASP3_HUMAN P42574 175 CASP7_HUMAN P55210 198 CATB_HUMAN P07858 77 CB044_HUMAN Q9H6R7 508 CBL_HUMAN P22681 806 CBWD1_HUMAN Q9BRT8 184 CBWD2_HUMAN Q8IUF1 184 CBWD3_HUMAN Q5JTY5 184 CBWD5_HUMAN Q5RIA9 184 CBWD6_HUMAN Q4V339 184 CBWD7_HUMAN A6NM15 36 CC104_HUMAN Q96G28 141 CC104_HUMAN Q96G28 144 CC124_HUMAN Q96CT7 149 CC131_HUMAN O60293 335 CC50A_HUMAN Q9NV96 12 CCD43_HUMAN Q96MW1 16 CCD53_HUMAN Q9Y3C0 4 CCD91_HUMAN Q7Z6B0 99 CCD97_HUMAN Q96F63 52 CCDC9_HUMAN Q9Y3X0 299 CCNT2_HUMAN O60583 454 CD2L1_HUMAN P21127 405 CD2L5_HUMAN Q14004 1353 CDC27_HUMAN P30260 236 CDC27_HUMAN P30260 243 CDC5L_HUMAN Q99459 391 CDCA7_HUMAN Q9BWT1 39 CDV3_HUMAN Q9UKY7 122 CDYL1_HUMAN Q9Y232 210 CE022_HUMAN Q49AR2 196 CE152_HUMAN O94986 62 CE170_HUMAN Q5SW79 936 CE170_HUMAN Q5SW79 1324 CEBPZ_HUMAN Q03701 774 CEBPZ_HUMAN Q03701 917 CEBPZ_HUMAN Q03701 955 CH041_HUMAN Q6NXR4 4 CH082_HUMAN Q6P1X6 25 CH60_HUMAN P10809 111 CH60_HUMAN P10809 452 CH60_HUMAN P10809 504 CHD3_HUMAN Q12873 372 CHD4_HUMAN Q14839 363 CHD5_HUMAN Q8TDI0 336 CHD4_HUMAN Q14839 1233 CHD7_HUMAN Q9P2D1 2285 CHM4A_HUMAN Q9BY43 80 CHM4B_HUMAN Q9H444 83 CHM4C_HUMAN Q96CF2 83 CI080_HUMAN Q9NRY2 57 CJ018_HUMAN Q5VWN6 1207 CJ047_HUMAN Q86WR7 109 CK059_HUMAN Q6IAA8 72 CL035_HUMAN Q9HCM1 359 CL035_HUMAN Q9HCM1 501 CL043_HUMAN Q96C57 72 CL043_HUMAN Q96C57 204 CLAP1_HUMAN Q7Z460 1218 CLCA_HUMAN P09496 76 CLCA_HUMAN P09496 92 CLIC1_HUMAN O00299 141 CLIP1_HUMAN P30622 397 CLSPN_HUMAN Q9HAW4 563 CND2_HUMAN Q15003 170 CND2_HUMAN Q15003 199 CND2_HUMAN Q15003 366 CND2_HUMAN Q15003 380 CNDH2_HUMAN Q6IBW4 459 CO6A3_HUMAN P12111 2615 COBL1_HUMAN Q53SF7 983 COPA_HUMAN P53621 188 COPA_HUMAN P53621 856 COPB2_HUMAN P35606 854 COR1A_HUMAN P31146 394 CP088_HUMAN Q1ED39 182 CP110_HUMAN Q7Z7A1 801 CP110_HUMAN Q7Z7A1 1395 CPIN1_HUMAN Q6FI81 214 CPNE1_HUMAN Q99829 464 CPNE3_HUMAN O75131 428 CPSF6_HUMAN Q16630 54 CPSF7_HUMAN Q8N684 29 CPSF7_HUMAN Q8N684 33 CPSF7_HUMAN Q8N684 324 CPZIP_HUMAN Q6JBY9 272 CQ056_HUMAN Q96N21 380 CQ085_HUMAN Q53F19 157 CQ085_HUMAN Q53F19 231 CR025_HUMAN Q96B23 44 CREB1_HUMAN P16220 116 CREB1_HUMAN P16220 229 CROCC_HUMAN Q5TZA2 578 CS043_HUMAN Q9BQ61 62 CS044_HUMAN Q9H6X5 368 CSN1_HUMAN Q13098 94 CSRN2_HUMAN Q9H175 39 CSTF3_HUMAN Q12996 576 CTBL1_HUMAN Q8WYA6 66 CTCF_HUMAN P49711 46 CTNB1_HUMAN P35222 115 CTND1_HUMAN O60716 161 CTR9_HUMAN Q6PD62 1120 CUL4B_HUMAN Q13620 25 CUTC_HUMAN Q9NTM9 33 CUX1_HUMAN P39880 1339 CYB5B_HUMAN O43169 10 DBPA_HUMAN P16989 144 DBPA_HUMAN P16989 161 DBPA_HUMAN P16989 269 DBPA_HUMAN P16989 137 YBOX1_HUMAN P67809 105 YBOX2_HUMAN Q9Y2T7 140 DCNL2_HUMAN Q6PH85 42 DCTN1_HUMAN Q14203 302 DD19A_HUMAN Q9NUU7 4 DDX1_HUMAN Q92499 439 DDX24_HUMAN Q9GZR7 296 DDX46_HUMAN Q7L014 871 DDX46_HUMAN Q7L014 922 DDX59_HUMAN Q5T1V6 43 DESM_HUMAN P17661 264 DFFA_HUMAN O00273 6 DFFA_HUMAN O00273 221 DGCR8_HUMAN Q8WYQ5 248 DGCR8_HUMAN Q8WYQ5 396 DGKH_HUMAN Q86XP1 582 DGKH_HUMAN Q86XP1 698 DGLB_HUMAN Q8NCG7 548 DHAK_HUMAN Q3LXA3 362 DHX30_HUMAN Q7L2E3 206 DHX37_HUMAN Q8IY37 573 DHX9_HUMAN Q08211 96 DHX9_HUMAN Q08211 167 DIAP1_HUMAN O60610 648 DIDO1_HUMAN Q9BTC0 987 DIDO1_HUMAN Q9BTC0 1250 DIDO1_HUMAN Q9BTC0 1352 DIDO1_HUMAN Q9BTC0 1518 DLG1_HUMAN Q12959 412 DNJC7_HUMAN Q99615 8 DNM1L_HUMAN O00429 503 DNM1L_HUMAN O00429 579 DNM3A_HUMAN Q9Y6K1 438 DOC10_HUMAN Q96BY6 327 DOHH_HUMAN Q9BU89 8 DOT1L_HUMAN Q8TEK3 1333 DP13A_HUMAN Q9UKG1 444 DPOD1_HUMAN P28340 102 DPOLA_HUMAN P09884 83 DPP9_HUMAN Q86TI2 13 DPYL4_HUMAN O14531 456 DREB_HUMAN Q16643 340 DREB_HUMAN Q16643 477 DSRAD_HUMAN P55265 214 DTL_HUMAN Q9NZJ0 578 DTX3L_HUMAN Q8TDB6 217 DYHC1_HUMAN Q14204 4220 DYHC1_HUMAN Q14204 4367 E400N_HUMAN Q6ZTU2 183 EP400_HUMAN Q96L91 194 E41L2_HUMAN O43491 912 EAP1_HUMAN Q9H1B7 132 EBP2_HUMAN Q99848 211 ECE1_HUMAN P42892 33 ECT2_HUMAN Q9H8V3 628 EDC4_HUMAN Q6P2E9 57 EDC4_HUMAN Q6P2E9 485 EDC4_HUMAN Q6P2E9 490 EDC4_HUMAN Q6P2E9 662 EDC4_HUMAN Q6P2E9 796 EDRF1_HUMAN Q3B7T1 115 EEA1_HUMAN Q15075 127 EEA1_HUMAN Q15075 132 EF1A1_HUMAN P68104 403 EF1A3_HUMAN Q5VTE0 EF1B_HUMAN P24534 102 EF1D_HUMAN P29692 158 EF2_HUMAN P13639 611 EH1L1_HUMAN Q8N3D4 1329 EHBP1_HUMAN Q8NDI1 274 EHD1_HUMAN Q9H4M9 415 EHMT1_HUMAN Q9H9B1 329 EHMT1_HUMAN Q9H9B1 481 EHMT2_HUMAN Q96KQ7 453 EIF3B_HUMAN P55884 184 EIF3G_HUMAN O75821 7 EIF3J_HUMAN O75822 50 ELF1_HUMAN P32519 145 ENOA_HUMAN P06733 203 ENPL_HUMAN P14625 28 ENPL_HUMAN P14625 59 EP15_HUMAN P42566 618 EP15R_HUMAN Q9UBC2 569 EPC1_HUMAN Q9H2F5 27 EPN1_HUMAN Q9Y6I3 460 EPN2_HUMAN O95208 339 ERC6L_HUMAN Q2NKX8 801 ERCC6_HUMAN Q03468 52 ERF_HUMAN P50548 191 ERF3A_HUMAN P15170 39 ERIC1_HUMAN Q86X53 276 ESYT2_HUMAN A0FGR8 759 ETUD1_HUMAN Q7Z2Z2 932 EXDL2_HUMAN Q9NVH0 198 F101B_HUMAN Q8N5W9 61 F107B_HUMAN Q9H098 5 F117B_HUMAN Q6P1L5 374 F125A_HUMAN Q96EY5 172 F169A_HUMAN Q9Y6X4 446 FA13A_HUMAN O94988 594 FA21A_HUMAN Q641Q2 1134 FA21B_HUMAN Q5SNT6 1046 FA21C_HUMAN Q9Y4E1 1113 FA21D_HUMAN Q5SRD0 101 FA29A_HUMAN Q7Z4H7 568 FA44A_HUMAN Q8NFC6 1483 FA44A_HUMAN Q8NFC6 1708 FA44A_HUMAN Q8NFC6 2044 FAS_HUMAN P49327 1165 FETUA_HUMAN P02765 133 FIP1_HUMAN Q6UN15 158 FKB15_HUMAN Q5T1M5 306 FLI1_HUMAN Q01543 20 FLNA_HUMAN P21333 25 FLNA_HUMAN P21333 1048 FLNA_HUMAN P21333 1336 FLNA_HUMAN P21333 1504 FLNA_HUMAN P21333 2536 FLNA_HUMAN P21333 34 FLNB_HUMAN O75369 7 FLNC_HUMAN Q14315 27 FLNB_HUMAN O75369 478 FLNB_HUMAN O75369 1021 FLNB_HUMAN O75369 1476 FNBP1_HUMAN Q96RU3 519 FNBP4_HUMAN Q8N3X1 153 FNBP4_HUMAN Q8N3X1 425 FNBP4_HUMAN Q8N3X1 777 FOXJ2_HUMAN Q9P0K8 212 FOXK1_HUMAN P85037 80 FOXO3_HUMAN O43524 54 FOXP4_HUMAN Q8IVH2 406 FRAP_HUMAN P42345 2459 FRYL_HUMAN O94915 1512 FUBP1_HUMAN Q96AE4 83 FUBP1_HUMAN Q96AE4 181 FUBP1_HUMAN Q96AE4 139 FUBP2_HUMAN Q92945 183 FUBP2_HUMAN Q92945 128 FUBP3_HUMAN Q96I24 34 FUBP3_HUMAN Q96I24 159 FUS_HUMAN P35637 355 FXR2_HUMAN P51116 561 FYB_HUMAN O15117 446 FYB_HUMAN O15117 655 FYN_HUMAN P06241 19 FYTD1_HUMAN Q96QD9 31 THOC4_HUMAN Q86V81 6 FYV1_HUMAN Q9Y2I7 989 FYV1_HUMAN Q9Y2I7 1607 G3P_HUMAN P04406 89 GABP1_HUMAN Q06547 303 GABP2_HUMAN Q8TAK5 304 GALT_HUMAN P07902 18 GAPD1_HUMAN Q14C86 1102 GATA2_HUMAN P23769 46 GBF1_HUMAN Q92538 368 GCFC_HUMAN Q9Y5B6 221 GCP2_HUMAN Q9BSJ2 772 GCP60_HUMAN Q9H3P7 15 GCP60_HUMAN Q9H3P7 343 GDIR2_HUMAN P52566 19 GDIR2_HUMAN P52566 55 GELS_HUMAN P06396 403 GELS_HUMAN P06396 639 GEMI5_HUMAN Q8TEQ6 1319 GEMI8_HUMAN Q9NWZ8 169 GEN_HUMAN Q17RS7 623 GFPT1_HUMAN Q06210 260 GGA3_HUMAN Q9NZ52 333 GGA3_HUMAN Q9NZ52 517 GIT1_HUMAN Q9Y2X7 418 GIT1_HUMAN Q9Y2X7 632 GIT2_HUMAN Q14161 625 GLGB_HUMAN Q04446 307 GLRX3_HUMAN O76003 101 GLU2B_HUMAN P14314 94 GLU2B_HUMAN P14314 101 GLU2B_HUMAN P14314 226 GMIP_HUMAN Q9P107 424 GMIP_HUMAN Q9P107 472 GMIP_HUMAN Q9P107 842 GNL1_HUMAN P36915 49 GNL1_HUMAN P36915 52 GNL1_HUMAN P36915 343 GOGB1_HUMAN Q14789 1245 GOGB1_HUMAN Q14789 1801 GON4L_HUMAN Q3T8J9 481 GPKOW_HUMAN Q92917 37 GPKOW_HUMAN Q92917 98 GPN1_HUMAN Q9HCN4 311 GPTC8_HUMAN Q9UKJ3 882 GRDN_HUMAN Q3V6T2 219 GRDN_HUMAN Q3V6T2 484 GRIN1_HUMAN Q7Z2K8 306 GSDMD_HUMAN P57764 87 GSDMD_HUMAN P57764 275 GSTP1_HUMAN P09211 91 GTF2I_HUMAN P78347 105 H2AY_HUMAN O75367 172 H4_HUMAN P62805 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555 NCOR1_HUMAN O75376 1826 NCOR2_HUMAN Q9Y618 377 NCOR2_HUMAN Q9Y618 1926 NDRG1_HUMAN Q92597 9 NEB2_HUMAN Q96SB3 551 NED4L_HUMAN Q96PU5 345 NEDD1_HUMAN Q8NHV4 434 NEDD4_HUMAN P46934 279 NEK1_HUMAN Q96PY6 949 NEK4_HUMAN P51957 380 NEK9_HUMAN Q8TD19 841 NELFA_HUMAN Q9H3P2 299 NFAC1_HUMAN O95644 110 NFAC2_HUMAN Q13469 66 NFKB2_HUMAN Q00653 10 NFRKB_HUMAN Q6P4R8 5 NFRKB_HUMAN Q6P4R8 496 NHERF_HUMAN O14745 4 NIPA_HUMAN Q86WB0 295 NIPA_HUMAN Q86WB0 449 NIPBL_HUMAN Q6KC79 472 NKTR_HUMAN P30414 959 NOL1_HUMAN P46087 207 NOL1_HUMAN P46087 230 NOL5_HUMAN Q9Y2X3 124 NOP14_HUMAN P78316 319 NP1L1_HUMAN P55209 57 NP1L1_HUMAN P55209 183 NP1L4_HUMAN Q99733 8 NP1L4_HUMAN Q99733 46 NP60_HUMAN Q49A26 255 NPAT_HUMAN Q14207 733 NPM_HUMAN P06748 6 NS1BP_HUMAN Q9Y6Y0 238 NSBP1_HUMAN P82970 57 NSUN2_HUMAN Q08J23 108 NSUN2_HUMAN Q08J23 499 NSUN2_HUMAN Q08J23 664 NU153_HUMAN P49790 358 NUCB2_HUMAN P80303 237 NUCB2_HUMAN P80303 258 NUCKS_HUMAN Q9H1E3 29 NUCL_HUMAN P19338 636 NUDC3_HUMAN Q8IVD9 119 NUDC3_HUMAN Q8IVD9 125 NUFP2_HUMAN Q7Z417 451 NUMA1_HUMAN Q14980 1747 NUMA1_HUMAN Q14980 1829 NUP43_HUMAN Q8NFH3 58 NUP50_HUMAN Q9UKX7 126 NUP93_HUMAN Q8N1F7 157 ODPB_HUMAN P11177 37 OFD1_HUMAN O75665 853 ORAV1_HUMAN Q8WV07 9 OSBL8_HUMAN Q9BZF1 806 OTU6B_HUMAN Q8N6M0 80 OTUD4_HUMAN Q01804 9 OXR1_HUMAN Q8N573 449 P4R3A_HUMAN Q6IN85 692 P66B_HUMAN Q8WXI9 344 PA24A_HUMAN P47712 522 PABP2_HUMAN Q86U42 111 PAIRB_HUMAN Q8NC51 337 PAK1_HUMAN Q13153 90 PAK2_HUMAN Q13177 89 PAK2_HUMAN Q13177 148 PALLD_HUMAN Q8WX93 432 PARG_HUMAN Q86W56 256 PARP1_HUMAN P09874 72 PARP1_HUMAN P09874 214 PAWR_HUMAN Q96IZ0 131 PAXI_HUMAN P49023 5 PAXI_HUMAN P49023 102 PAXI_HUMAN P49023 335 PB1_HUMAN Q86U86 21 PCBP1_HUMAN Q15365 203 PCBP1_HUMAN Q15365 220 PCBP1_HUMAN Q15365 275 PCBP2_HUMAN Q15366 282 PCF11_HUMAN O94913 1288 PCM1_HUMAN Q15154 193 PCM1_HUMAN Q15154 1551 PCNT_HUMAN O95613 80 PDIP3_HUMAN Q9BY77 234 PDLI1_HUMAN O00151 54 PDXD1_HUMAN Q6P996 584 PEBB_HUMAN Q13951 120 PFTK1_HUMAN O94921 56 PGK1_HUMAN P00558 68 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Q8IZ40 391 RD23B_HUMAN P54727 165 RED_HUMAN Q13123 108 RED_HUMAN Q13123 324 REL_HUMAN Q04864 86 RENT1_HUMAN Q92900 75 REPS1_HUMAN Q96D71 386 REPS1_HUMAN Q96D71 459 REPS1_HUMAN Q96D71 465 REQU_HUMAN Q92785 115 REQU_HUMAN Q92785 243 REST_HUMAN Q13127 941 RFC1_HUMAN P35251 167 RFC1_HUMAN P35251 723 RFX7_HUMAN Q2KHR2 479 RGAP1_HUMAN Q9H0H5 273 RGPD1_HUMAN Q68DN6 1499 RGPD2_HUMAN P0C839 764 RGPD3_HUMAN A6NKT7 1515 RGPD4_HUMAN Q7Z3J3 1515 RGPD5_HUMAN Q99666 1514 RGPD6_HUMAN Q53T03 1514 RGPD8_HUMAN O14715 504 RGS10_HUMAN O43665 12 RGS10_HUMAN O43665 14 RHG04_HUMAN P98171 403 RHG25_HUMAN P42331 387 RHG25_HUMAN P42331 397 RHG30_HUMAN Q7Z6I6 363 RHG30_HUMAN Q7Z6I6 592 RHG30_HUMAN Q7Z6I6 907 RHGBA_HUMAN Q6P4F7 256 RHOA_HUMAN P61586 90 RHOC_HUMAN P08134 RIF1_HUMAN Q5UIP0 1809 RIF1_HUMAN Q5UIP0 2000 RIMB1_HUMAN O95153 44 RIMB1_HUMAN O95153 1807 RING1_HUMAN Q06587 31 RIOK1_HUMAN Q9BRS2 129 RIPK1_HUMAN Q13546 558 RIR2_HUMAN P31350 29 RL17_HUMAN P18621 110 RL5_HUMAN P46777 136 RL5_HUMAN P46777 168 RN168_HUMAN Q8IYW5 250 RN213_HUMAN Q63HN8 355 RN219_HUMAN Q5W0B1 433 RN220_HUMAN Q5VTB9 413 RNF5_HUMAN Q99942 8 RNZ1_HUMAN Q9H777 279 ROA0_HUMAN Q13151 62 ROA0_HUMAN Q13151 73 ROA2_HUMAN P22626 76 ROA2_HUMAN P22626 130 ROA3_HUMAN P51991 90 ROA3_HUMAN P51991 115 ROA3_HUMAN P51991 178 ROCK1_HUMAN Q13464 1113 RPAP3_HUMAN Q9H6T3 124 RPAP3_HUMAN Q9H6T3 451 RPB9_HUMAN P36954 4 RPC4_HUMAN P05423 131 RPC5_HUMAN Q9NVU0 543 RPGF6_HUMAN Q8TEU7 1282 RREB1_HUMAN Q92766 1173 RRMJ3_HUMAN Q8IY81 346 RRP12_HUMAN Q5JTH9 556 RRP12_HUMAN Q5JTH9 1161 RRP1B_HUMAN Q14684 275 RS20_HUMAN P60866 5 RS23_HUMAN P62266 88 RS28_HUMAN P62857 54 RS3_HUMAN P23396 32 RSRC1_HUMAN Q96IZ7 238 RTF1_HUMAN Q92541 140 RTN4_HUMAN Q9NQC3 84 RTN4_HUMAN Q9NQC3 905 RU1C_HUMAN P09234 10 RU2A_HUMAN P09661 45 RUSD2_HUMAN Q8IZ73 441 RUXF_HUMAN P62306 52 S11IP_HUMAN Q8N1F8 372 S12A2_HUMAN P55011 66 S2546_HUMAN Q96AG3 10 S30BP_HUMAN Q9UHR5 44 SAFB1_HUMAN Q15424 146 SAFB1_HUMAN Q15424 262 SAFB2_HUMAN Q14151 261 SAFB1_HUMAN Q15424 360 SAFB2_HUMAN Q14151 359 SAFB1_HUMAN Q15424 796 SAFB2_HUMAN Q14151 820 SAFB2_HUMAN Q14151 153 SAFB2_HUMAN Q14151 183 SAHH2_HUMAN O43865 5 SAHH2_HUMAN O43865 73 SAHH2_HUMAN O43865 83 SAHH3_HUMAN Q96HN2 109 SAM4B_HUMAN Q5PRF9 412 SAP_HUMAN P07602 312 SAP_HUMAN P07602 405 SAPS1_HUMAN Q9UPN7 358 SASH3_HUMAN O75995 55 SASH3_HUMAN O75995 115 SATB1_HUMAN Q01826 254 SATT_HUMAN P43007 12 SC16A_HUMAN O15027 341 SC16A_HUMAN O15027 837 SC24B_HUMAN O95487 295 SCAM3_HUMAN O14828 39 SCMH1_HUMAN Q96GD3 511 SCO1_HUMAN O75880 188 SCOC_HUMAN Q9UIL1 87 SDCG1_HUMAN O60524 779 SEC13_HUMAN P55735 14 SEC20_HUMAN Q12981 32 SENP6_HUMAN Q9GZR1 49 SEPT9_HUMAN Q9UHD8 282 SETD2_HUMAN Q9BYW2 647 SETD2_HUMAN Q9BYW2 1169 SETX_HUMAN Q7Z333 1534 SF01_HUMAN Q15637 448 SF3A1_HUMAN Q15459 32 SF3A1_HUMAN Q15459 503 SF3B1_HUMAN O75533 34 SF3B2_HUMAN Q13435 291 SF3B2_HUMAN Q13435 753 SF3B4_HUMAN Q15427 12 SFPQ_HUMAN P23246 525 SFR14_HUMAN Q8IX01 732 SFR14_HUMAN Q8IX01 901 SFR14_HUMAN Q8IX01 922 SFRIP_HUMAN Q99590 407 SFRS2_HUMAN Q01130 70 SFRS2_HUMAN Q01130 73 SFRS3_HUMAN P84103 4 SFRS5_HUMAN Q13243 52 SFRS6_HUMAN Q13247 167 SGOL1_HUMAN Q5FBB7 206 SH2D3_HUMAN Q8N5H7 375 SHOT1_HUMAN A0MZ66 129 SIPA1_HUMAN Q96FS4 814 SIX4_HUMAN Q9UIU6 296 SKI_HUMAN P12755 527 SKT_HUMAN Q5T5P2 609 SLD5_HUMAN Q9BRT9 6 SLK_HUMAN Q9H2G2 403 SLMAP_HUMAN Q14BN4 464 SLU7_HUMAN O95391 7 SMC2_HUMAN O95347 1116 SMCA4_HUMAN P51532 1381 SMCE1_HUMAN Q969G3 264 SMHD1_HUMAN A6NHR9 5 SMRC2_HUMAN Q8TAQ2 814 SMRD2_HUMAN Q92925 135 SNPC4_HUMAN Q5SXM2 1168 SNX12_HUMAN Q9UMY4 21 SNX2_HUMAN O60749 84 SNX29_HUMAN Q8TEQ0 182 SNX3_HUMAN O60493 32 SNX6_HUMAN Q9UNH7 10 SOBP_HUMAN A7XYQ1 298 SODC_HUMAN P00441 93 SODC_HUMAN P00441 102 SON_HUMAN P18583 153 SON_HUMAN P18583 352 SON_HUMAN P18583 1640 SON_HUMAN P18583 1718 SP1_HUMAN P08047 199 SP110_HUMAN Q9HB58 353 SP3_HUMAN Q02447 275 SP3_HUMAN Q02447 530 SPAS2_HUMAN Q86XZ4 145 SPAST_HUMAN Q9UBP0 470 SPD2B_HUMAN A1X283 682 SPEC1_HUMAN Q5M775 213 SPEE_HUMAN P19623 6 SPF27_HUMAN O75934 14 SPF30_HUMAN O75940 62 SPG20_HUMAN Q8N0X7 496 SPS2L_HUMAN Q9NUQ6 119 SPT6H_HUMAN Q7KZ85 1047 SPTA2_HUMAN Q13813 500 SPTA2_HUMAN Q13813 1478 SPTN2_HUMAN O15020 1752 SR140_HUMAN O15042 704 SR140_HUMAN O15042 712 SR140_HUMAN O15042 725 SR140_HUMAN O15042 737 SRC_HUMAN P12931 45 SRCAP_HUMAN Q6ZRS2 2275 SRFB1_HUMAN Q8NEF9 211 SRP68_HUMAN Q9UHB9 537 SRPK1_HUMAN Q96SB4 412 SRRM2_HUMAN Q9UQ35 147 SRRM2_HUMAN Q9UQ35 1149 SSA27_HUMAN O60232 81 SSBP3_HUMAN Q9BWW4 286 SSF1_HUMAN Q9NQ55 245 SSFA2_HUMAN P28290 627 SSH2_HUMAN Q76I76 963 SSRP1_HUMAN Q08945 173 STAP1_HUMAN Q9ULZ2 170 STK10_HUMAN O94804 332 STK24_HUMAN Q9Y6E0 325 STK39_HUMAN Q9UEW8 435 STK4_HUMAN Q13043 349 STRN_HUMAN O43815 35 STRN_HUMAN O43815 436 STX10_HUMAN O60499 138 STX10_HUMAN O60499 196 STX12_HUMAN Q86Y82 217 STX17_HUMAN P56962 201 STX7_HUMAN O15400 204 SUGT1_HUMAN Q9Y2Z0 20 SYAP1_HUMAN Q96A49 281 SYEP_HUMAN P07814 929 SYF2_HUMAN O95926 12 SYG_HUMAN P41250 56 SYMPK_HUMAN Q92797 28 SYNC_HUMAN O43776 409 SYNE1_HUMAN Q8NF91 8279 SYNE2_HUMAN Q8WXH0 4215 SYWC_HUMAN P23381 83 T106B_HUMAN Q9NUM4 19 T106C_HUMAN Q9BVX2 23 T2EA_HUMAN P29083 303 T2FA_HUMAN P35269 272 TACC1_HUMAN O75410 323 TACC1_HUMAN O75410 500 TACC2_HUMAN O95359 371 TACC3_HUMAN Q9Y6A5 21 TACC3_HUMAN Q9Y6A5 286 TAD1L_HUMAN Q96BN2 78 TAF11_HUMAN Q15544 34 TAF7_HUMAN Q15545 100 TBA1A_HUMAN Q71U36 33 TBA1B_HUMAN P68363 TBA1C_HUMAN Q9BQE3 TBA3C_HUMAN Q13748 TBA3E_HUMAN Q6PEY2 TBA1A_HUMAN Q71U36 245 TBA1B_HUMAN P68363 TBA1C_HUMAN Q9BQE3 TBA3C_HUMAN Q13748 TBA3E_HUMAN Q6PEY2 TBA4A_HUMAN P68366 TBA8_HUMAN Q9NY65 TBB2A_HUMAN Q13885 114 TBB2B_HUMAN Q9BVA1 TBB2C_HUMAN P68371 TBB3_HUMAN Q13509 TBB5_HUMAN P07437 TBB2C_HUMAN P68371 114 TBB5_HUMAN P07437 TBCC_HUMAN Q15814 153 TBCD4_HUMAN O60343 272 TBCD4_HUMAN O60343 275 TBL1R_HUMAN Q9BZK7 152 TBL1R_HUMAN Q9BZK7 85 TBL1X_HUMAN O60907 TBL1R_HUMAN Q9BZK7 152 TBL1Y_HUMAN Q9BQ87 162 TBL1X_HUMAN O60907 164 TCEA1_HUMAN P23193 124 TCF20_HUMAN Q9UGU0 1219 TCOF_HUMAN Q13428 1101 TCOF_HUMAN Q13428 1242 TCPD_HUMAN P50991 268 TCPD_HUMAN P50991 456 TCPE_HUMAN P48643 65 TCPE_HUMAN P48643 153 TCPZ_HUMAN P40227 404 TCTP_HUMAN P13693 25 TDRD6_HUMAN O60522 1918 TEX2_HUMAN Q8IWB9 96 TEX2_HUMAN Q8IWB9 356 TF2B_HUMAN Q00403 207 TF2L1_HUMAN Q9NZI6 22 TFCP2_HUMAN Q12800 42 UBIP1_HUMAN Q9NZI7 39 TF3A_HUMAN Q92664 18 TF65_HUMAN Q04206 97 TGS1_HUMAN Q96RS0 337 TGS1_HUMAN Q96RS0 343 THOC4_HUMAN Q86V81 93 THOC5_HUMAN Q13769 17 THOP1_HUMAN P52888 13 TIF1A_HUMAN O15164 784 TIF1B_HUMAN Q13263 105 TIF1B_HUMAN Q13263 148 TIF1B_HUMAN Q13263 685 TIF1B_HUMAN Q13263 688 TIF1B_HUMAN Q13263 726 TIM_HUMAN Q9UNS1 579 TINF2_HUMAN Q9BSI4 207 TLK2_HUMAN Q86UE8 132 TM168_HUMAN Q9H0V1 426 TM1L2_HUMAN Q6ZVM7 157 TMUB1_HUMAN Q9BVT8 60 TNIP2_HUMAN Q8NFZ5 194 TNR6A_HUMAN Q8NDV7 1542 TOE1_HUMAN Q96GM8 7 TOE1_HUMAN Q96GM8 373 TOIP1_HUMAN Q5JTV8 226 TOIP1_HUMAN Q5JTV8 304 TOLIP_HUMAN Q9H0E2 36 TOM1_HUMAN O60784 157 TOM1_HUMAN O60784 179 TOM1_HUMAN O60784 184 TOM1_HUMAN O60784 393 TOP2B_HUMAN Q02880 1470 TP53B_HUMAN Q12888 211 TP53B_HUMAN Q12888 317 TP53B_HUMAN Q12888 829 TP53B_HUMAN Q12888 1478 TPR_HUMAN P12270 1837 TPR_HUMAN P12270 2147 TPRGL_HUMAN Q5T0D9 9 TR150_HUMAN Q9Y2W1 574 TRBP2_HUMAN Q15633 234 TREF1_HUMAN Q96PN7 760 TRI33_HUMAN Q9UPN9 829 TRIP4_HUMAN Q15650 122 TRIP4_HUMAN Q15650 288 TRM1L_HUMAN Q7Z2T5 44 TRS85_HUMAN Q9Y2L5 853 TSC1_HUMAN Q92574 638 TSR1_HUMAN Q2NL82 332 TTC1_HUMAN Q99614 65 TTC4_HUMAN O95801 254 TTF2_HUMAN Q9UNY4 826 TYB10_HUMAN P63313 6 TYSY_HUMAN P04818 119 TYY1_HUMAN P25490 119 U119A_HUMAN Q13432 44 U119B_HUMAN A6NIH7 51 U2AF2_HUMAN P26368 128 UAP1L_HUMAN Q3KQV9 299 UAP56_HUMAN Q13838 25 UBA1_HUMAN P22314 427 UBA3_HUMAN Q8TBC4 25 UBAP2_HUMAN Q5T6F2 201 UBAP2_HUMAN Q5T6F2 262 UBAP2_HUMAN Q5T6F2 854 UBE2O_HUMAN Q9C0C9 437 UBE2O_HUMAN Q9C0C9 1225 UBFD1_HUMAN O14562 232 UBN1_HUMAN Q9NPG3 136 UBP10_HUMAN Q14694 125 UBP10_HUMAN Q14694 138 UBP10_HUMAN Q14694 217 UBP14_HUMAN P54578 76 UBP14_HUMAN P54578 227 UBP19_HUMAN O94966 619 UBP2L_HUMAN Q14157 298 UBP2L_HUMAN Q14157 411 UBP2L_HUMAN Q14157 850 UBP34_HUMAN Q70CQ2 3366 UBP36_HUMAN Q9P275 576 UBP42_HUMAN Q9H9J4 764 UBP5_HUMAN P45974 134 UBP5_HUMAN P45974 767 UBP5_HUMAN P45974 782 UBP7_HUMAN Q93009 50 UBQL1_HUMAN Q9UMX0 15 UBR4_HUMAN Q5T4S7 2903 UBXN7_HUMAN O94888 109 UBXN7_HUMAN O94888 400 UGPA_HUMAN Q16851 15 UH1BL_HUMAN A0JNW5 1173 UHRF1_HUMAN Q96T88 118 URP2_HUMAN Q86UX7 344 USE1_HUMAN Q9NZ43 129 USF2_HUMAN Q15853 120 USO1_HUMAN O60763 757 UTRO_HUMAN P46939 261 VAMP2_HUMAN P63027 68 VAMP3_HUMAN Q15836 51 VATD_HUMAN Q9Y5K8 117 VIME_HUMAN P08670 82 VIME_HUMAN P08670 85 VIME_HUMAN P08670 90 VIME_HUMAN P08670 257 VIME_HUMAN P08670 259 VIME_HUMAN P08670 331 VIME_HUMAN P08670 429 VP13D_HUMAN Q5THJ4 2610 VPS4A_HUMAN Q9UN37 230 VRK1_HUMAN Q99986 231 WAPL_HUMAN Q7Z5K2 154 WASF1_HUMAN Q92558 247 WASF2_HUMAN Q9Y6W5 242 WASF2_HUMAN Q9Y6W5 411 WASH1_HUMAN A8K0Z3 298 WDR33_HUMAN Q9C0J8 1183 WDR44_HUMAN Q5JSH3 83 WDR55_HUMAN Q9H6Y2 20 WDR62_HUMAN O43379 1301 WDR92_HUMAN Q96MX6 118 WFS1_HUMAN O76024 75 WFS1_HUMAN O76024 211 WIPF1_HUMAN O43516 181 WNK1_HUMAN Q9H4A3 652 WNK1_HUMAN Q9H4A3 1069 WNK1_HUMAN Q9H4A3 2025 WRIP1_HUMAN Q96S55 192 WWC2_HUMAN Q6AWC2 855 XPA_HUMAN P23025 5 YAP1_HUMAN P46937 111 YBOX1_HUMAN P67809 24 YBOX1_HUMAN P67809 112 YIPF3_HUMAN Q9GZM5 68 YJ005_HUMAN Q6ZSR9 117 YJ005_HUMAN Q6ZSR9 123 YM017_HUMAN A8MX80 223 YTDC2_HUMAN Q9H6S0 324 YTHD1_HUMAN Q9BYJ9 164 YTHD2_HUMAN Q9Y5A9 166 YTHD2_HUMAN Q9Y5A9 367 YTHD3_HUMAN Q7Z739 168 ZAP70_HUMAN P43403 290 ZBT34_HUMAN Q8NCN2 139 ZBT44_HUMAN Q8NCP5 157 ZC11A_HUMAN O75152 348 ZC11A_HUMAN O75152 530 ZC3H4_HUMAN Q9UPT8 67 ZC3H4_HUMAN Q9UPT8 741 ZC3HD_HUMAN Q5T200 159 ZC3HE_HUMAN Q6PJT7 523 ZCCHV_HUMAN Q7Z2W4 433 ZCCHV_HUMAN Q7Z2W4 491 ZCH18_HUMAN Q86VM9 361 ZCHC2_HUMAN Q9C0B9 234 ZCHC8_HUMAN Q6NZY4 343 ZEB1_HUMAN P37275 49 ZF161_HUMAN O43829 243 ZFAN6_HUMAN Q6FIF0 106 ZFAN6_HUMAN Q6FIF0 126 ZFPL1_HUMAN O95159 171 ZFX_HUMAN P17010 244 ZFY16_HUMAN Q7Z3T8 107 ZFY16_HUMAN Q7Z3T8 283 ZFY16_HUMAN Q7Z3T8 534 ZMYM3_HUMAN Q14202 255 ZMYM4_HUMAN Q5VZL5 928 ZN143_HUMAN P52747 151 ZN143_HUMAN P52747 182 ZN200_HUMAN P98182 188 ZN264_HUMAN O43296 159 ZN277_HUMAN Q9NRM2 6 ZN346_HUMAN Q9UL40 13 ZN644_HUMAN Q9H582 615 ZN646_HUMAN O15015 1005 ZN787_HUMAN Q6DD87 230 ZN828_HUMAN Q96JM3 585 ZNF24_HUMAN P17028 9 ZNF76_HUMAN P36508 13 ZNHI2_HUMAN Q9UHR6 144 ZYX_HUMAN Q15942 149

It is understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in light thereof will be suggested to persons skilled in the art and are to be included within the spirit and purview of this application and scope of the appended claims. All publications, accession numbers, patents, and patent applications cited herein are hereby incorporated by reference in their entirety for all purposes. 

1.-3. (canceled)
 4. An isolated proteolytic apoptotic polypeptide biomarker comprising an N-terminal sequence selected from SEQ ID NO:1 through SEQ ID NO:401. 5.-8. (canceled)
 9. A binding reagent that specifically binds to a polypeptide of claim 4, wherein said binding reagent does not substantially bind to a corresponding full-length protein comprising the polypeptide of claim
 4. 10. (canceled)
 11. The binding reagent of claim 9, wherein said binding reagent is an antibody.
 12. The antibody of claim 11, wherein said antibody is a mAb or a fragment thereof. 13.-21. (canceled)
 22. A binding reagent that specifically binds to an epitope of a cleavage junction, wherein said binding reagent does not substantially bind to either of the N-terminal or C-terminal fragments of said cleavage junction generated after proteolysis, wherein said cleavage junction comprises an amino acid sequence corresponding to the proteolytic apoptotic polypeptide biomarker of claim
 4. 23. The binding reagent of claim 22, wherein said binding reagent is an antibody. 24.-26. (canceled)
 27. A method of quantifying a level of a proteolytic polypeptide in a biological sample, the method comprising: adding an amount of a synthetic heavy isotope-labeled peptide, to a biological sample, wherein said heavy isotope-labeled peptide is a proteolytic polypeptide biomarker of claim 4 labeled with a heavy isotope; subjecting the biological sample to treatment with a protease or chemical thereby creating a proteolytic polypeptide comprising a sequence identical to the synthetic heavy isotope-labeled peptide; detecting the proteolytic polypeptide and the synthetic heavy isotope-labeled peptide using mass spectrometry; determining a level of the proteolytic polypeptide in the biological sample by comparing the level to the amount of the synthetic heavy isotope-labeled peptide.
 28. A method of detecting a proteolytic apoptotic polypeptide biomarker in a biological sample, said method comprising the steps of: (a) contacting a biological sample with a binding reagent of claim 9; and (b) detecting said binding reagent, thereby detecting the proteolytic apoptotic polypeptide biomarker that specifically binds to the binding reagent.
 29. The method of claim 28, wherein said reagent is a mAb or a fragment thereof.
 30. A method of determining a level of apoptosis in a subject, the method comprising the steps of: (a) determining a level of a proteolytic apoptotic polypeptide biomarker in a biological sample from a subject; and (b) comparing said level of proteolytic apoptotic polypeptide biomarker to a proteolytic apoptotic signature corresponding to a predetermined level of apoptosis, thereby determining the level of apoptosis in said subject, wherein said proteolytic apoptotic polypeptide biomarker is formed from a pro-apoptotic polypeptide comprising a sequence selected from SEQ ID NO:1 through SEQ ID NO:401. 31.-33. (canceled)
 34. A method of determining a level of apoptosis in a subject, the method comprising the steps of: (a) determining a level of a proteolytic apoptotic cleavage junction in a biological sample from said subject; (b) determining a level of an N-terminal proteolytic apoptotic polypeptide biomarker corresponding to said proteolytic apoptotic cleavage junction; and (c) determining the ratio of proteolytic apoptotic polypeptide biomarker to proteolytic apoptotic cleavage junction in said biological sample, thereby determining the level of apoptosis in the subject.
 35. The method of claim 34, wherein said proteolytic apoptotic polypeptide biomarker comprises an N-terminal sequence selected from SEQ ID NO:1 through SEQ ID NO:401.
 36. (canceled)
 37. A method of diagnosing or providing a prognosis for a disease characterized by apoptosis in an individual, the method comprising the steps of: (a) detecting a first proteolytic apoptotic signature in a biological sample from said individual; and (b) comparing said first proteolytic apoptotic signature to a second proteolytic apoptotic signature corresponding to a diagnosis or prognosis for a disease characterized by apoptosis, thereby diagnosing or providing a prognosis for a disease characterized by apoptosis in said individual.
 38. The method of claim 37, further comprising the steps of: (c) comparing said first apoptotic signature to a third apoptotic signature corresponding to a diagnosis of no disease or a second prognosis for said disease; and (d) determining which of the second or third apoptotic signatures said first apoptotic signature most highly correlates to, thereby diagnosing or providing a prognosis for a disease characterized by apoptosis in said individual.
 39. The method of claim 37, wherein said disease is cancer.
 40. A method of determining the efficacy of a drug, the method comprising the steps of: (a) determining a level of a proteolytic polypeptide in a biological sample from a subject receiving a dose of said drug; (b) determining the level of the proteolytic polypeptide in a biological sample from a subject not receiving a dose of said drug; and (c) comparing said first and said second levels of the proteolytic polypeptide, thereby determining the efficacy of said drug, wherein said proteolytic polypeptide comprises an N-terminal sequence selected from SEQ ID NO:1 through SEQ ID NO:401.
 41. The method of claim 30, wherein step (a) comprises determining levels of a plurality of different proteolytic apoptotic polypeptide biomarkers in a biological sample from said subject; and step (b) comprises comparing levels of said plurality of different proteolytic apoptotic polypeptide biomarkers to a proteolytic apoptotic signature corresponding to a predetermined level of apoptosis, thereby determining the level of apoptosis in said subject; wherein said plurality of different proteolytic apoptotic polypeptide biomarkers are formed from a plurality of pro-apoptotic polypeptides each comprising a sequence selected from SEQ ID NO:1 through SEQ ID NO:401.
 42. The method of claim 30, wherein the proteolytic apoptotic signature comprises a level of said proteolytic apoptotic polypeptide biomarker corresponding to a predetermined level of apoptosis.
 43. The method of claim 30, wherein said proteolytic apoptotic polypeptide biomarker comprises an N-terminal sequence selected from SEQ ID NO:1 through SEQ ID NO:401.
 44. The method of claim 30, wherein said determining a level of a proteolytic apoptotic polypeptide biomarker in a biological sample from a subject comprises the use of a binding reagent, subtiligase, mass spectrometry, selected reaction monitoring, or multiple reaction monitoring.
 45. A method of determining a level of apoptosis in a subject, the method comprising the steps of: (a) determining a level of a proteolytic apoptotic cleavage junction in a biological sample from a subject; and (b) comparing said level of proteolytic apoptotic cleavage junction to a proteolytic apoptotic signature corresponding to a predetermined level of apoptosis, thereby determining the level of apoptosis in said subject, wherein said proteolytic apoptotic cleavage junction comprises a sequence selected from SEQ ID NO:1 through SEQ ID NO:401.
 46. The method of claim 45, wherein, step (a) comprises determining levels of a plurality of different proteolytic apoptotic cleavage junctions in a biological sample from said subject; and step (b) comprises comparing levels of said plurality of different proteolytic apoptotic cleavage junctions to a proteolytic apoptotic signature corresponding to a predetermined level of apoptosis, thereby determining the level of apoptosis in said subject; wherein said plurality of different proteolytic apoptotic cleavage junctions each comprise a sequence selected from SEQ ID NO:1 through SEQ ID NO:401. 